Non-coding RNA in T cell activation and function

Lind, Liza

January 2013

For a long time research has focused on the protein-coding mRNA, but there is a complex world of non-coding RNAs regulating the human body that we yet know very little about. Non-coding RNAs (ncRNAs) are involved in modulation of different cell processes including proliferation, differentiation and apoptosis. In the current study the role of ncRNAs in T cell activation and function was investigated. T cells are important mediators of immune responses, for example upon viral infections. The T helper cells (TH or CD4+ cells) are involved in orchestrating immune processes like aiding the activation of macrophages and enhancement of B cell function. The TH1 cell subtype is generally pro-inflammatory and IFNγ-secreting. There are regulatory T (Treg) cells that are involved in downregulation of TH1 cells, to decrease or terminate the immune response. It has been shown that upon repeated stimulation TH1 cells can switch into a Treg-like IL10-secreting anti-inflammatory phenotype. In the IL10-secreting Treg-like cells the microRNA 150 (miR-150) was found upregulated compared to IFNγ-secreting TH1 cells. Thus, miR-150 was believed to be a candidate in key regulation of the switch between the two phenotypes. Predicted target genes of miR-150 were identified using mRNA arrays investigating down-regulated genes in the IL10-secreting Treg-like subpopulation. In this thesis predicted targets of miR-150 were investigated using luciferase assays. Unfortunately no targets were identified. Upon isolation of IFNγ-secreting TH1 cells and Treg-like IL10-secreting cells, it was found that the ncRNA 886 (nc886) was upregulated in these activated cells, compared to resting TH cells. This indicates that nc886 has an important role in T cell activation. Nc886 has been shown to inhibit PKR activation in other cell types. The effect of nc886 on protein kinase R (PKR) was therefore investigated. PKR shuts down translation upon activation in response to viral double-stranded RNA or cellular stress. We showed that in an activated T cell phenotype nc886 is affecting PKR upon activation by dsRNA from HIV or synthetic origin. The PKR activation pattern is reversed in a resting T cell phenotype.

ncRNA 886

non-coding RNA 886

microRNA 150

miRNA 150

PKR

T cell activation

luciferase assay

Contrôle de la neuroinflammation par la kinase PKR dans les processus pathologiques de la maladie d'Alzheimer / Involvement of PKR-mediated inflammation in Alzheimer's disease pathology

Carret-Rebillat, Anne-Sophie

24 September 2014

La maladie d’Alzheimer (MA) est la pathologie neurodégénérative entraînant une démence la plus fréquente. Elle touche plus de 3% des plus de 65 ans. Les lésions cérébrales qui la constituent sont les dépôts de substance β amyloïde (Aβ) et les dégénérescences neurofibrillaires responsables de la mort neuronale, en particulier dans le cortex et l’hippocampe. Ces lésions s’accompagnent d’une réaction inflammatoire centrale qui participe au processus de neurodégénérescence. Les modèles murins d’endotoxémie reproduisent une réaction inflammatoire du système nerveux central comme observé chez l’homme. Nous avons utilisé un modèle murin d’endotoxémie par injections périphériques de LPS et mis en évidence une activation microgliale, une augmentation de la production d’Aβ et de l’expression de BACE1 ainsi qu’une altération du métabolisme dans l’hippocampe des animaux en réponse au LPS. Ces réactions sont contrôlées par la kinase de stress PKR (double-stranded RNA-dependant protein kinase) dont l’invalidation exerce in vivo un effet neuroprotecteur. La production d’Aβ serait régulée dans ce modèle par l’activation PKR-dépendante du facteur de transcription STAT3, responsable du contrôle transcriptionnel de BACE1. L’activation de PKR a été retrouvée à plusieurs niveaux du processus dégénératif associé à la MA et a été identifiée comme un potentiel biomarqueur diagnostique et pronostique de la maladie. Nos résultats confirment le rôle de PKR dans la pathogénèse de la MA et l’intérêt de l’inhibition de PKR pour la recherche thérapeutique. / Alzheimer's disease (AD) is the most common neurodegenerative disease leading to dementia. More than 3% of those over 65 years are affected. Pathological features of AD are β amyloid (Aβ) deposition and neurofibrillary tangles resulting in neuronal death, specifically in cortex and hippocampus. Brain inflammation is associated and involved in the neurodegeneration process. Murine models of endotoxemia show inflammation in the central nervous system as observed in humans. Using a model of endotoxemia by peripheral LPS injections in mice, we observed an activation of microglia, an increase of Aβ production and BACE1 expression and a decreased metabolism in the hippampus of LPS treated animals. These reactions are controlled by the stress kinase PKR (double stranded RNA-dependent protein kinase) whose invalidation exerts a neuroprotective effect in vivo. Aβ production in this model would be regulated by the PKR-dependent activation of the transcription factor STAT3, responsible for transcriptional control of BACE1. Activation of PKR is involved at several levels of the degenerative process associated with AD and has been identified as a potential diagnostic and prognostic biomarker of AD. These results confirm the role of PKR in the pathogenesis of AD and the interest of PKR down-regulation for therapeutic research.

Maladie d'Alzheimer

Inflammation systémique

Neuroinflammation

Endotoxémie

Pkr

Amyloïdogénèse

Alzheimer's disease

Endotoxemia

616.8

INHIBITION OF HOST INNATE IMMUNE RESPONSES THROUGH THE MODULATION OF CYTOPLASMIC STRESS GRANULES BY ENCEPHALOMYOCARDITIS VIRUS PROTEASE / 脳心筋炎ウイルス(EMCV)プロテアーゼによる細胞性ストレス顆粒形成の制御と抗ウイルス自然免疫応答の阻害機構

Ng Chen Seng

24 September 2014

京都大学 / 0048 / 新制・課程博士 / 博士(生命科学) / 甲第18627号 / 生博第318号 / 新制||生||42(附属図書館) / 31527 / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授 藤田 尚志, 教授 米原 伸, 教授 朝長 啓造 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

EMCV

Stress granule

MDA5

interferon

PKR

antiviral

innate immune response

460

RNase L Amplifies Interferon Signaling by Inducing Protein Kinase R-Mediated Antiviral Stress Granules

Manivannan, Praveen

January 2020

No description available.

Biology

Virology

PKR

RNase L

Rig-I

double-stranded RNA

interferon

stress granules

THE PHYSIOLOGICAL FUNCTION OF THE dsRNA-BINDING PROTEIN PACT/RAX, PROTEIN ACTIVATOR OF PKR AND ITS ROLE IN MOUSE DEVELOPMENT

Dickerman, Benjamin K.

24 August 2012

No description available.

Developmental Biology

Molecular Biology

PACT

RAX

PKR

Microtia

Mouse Development

Anterior Pituitary Proliferation

siRNA

miRNA

PKR DEPENDENT UPREGULATION OF IMMEDIATE EARLY GENES AND ANTI-INFLAMMATORY CYTOKINE IL-10

Chakrabarti, Arindam

01 May 2007

No description available.

Biology, Molecular

PKR

IL-10

c-jun

egr-1

immediate early genes

Atividade da proteína quinase dependente de RNA (PKR) no sistema nociceptivo em um modelo experimental de neuropatia periférica de origem viral / Double stranded RNA-activated protein kinase (PKR) activity in the nociceptive system in an experimental model of peripheral neuropathy of viral origin

Mota, Clarissa Maria Dias

25 February 2016

A proteína quinase dependente de RNA (PKR) é uma molécula sentinela ativada em situações de estresse celular, incluindo infecções virais. A ativação de PKR por meio de sua fosforilação aciona cascatas de sinalização intracelular envolvidas em respostas inflamatórias e inibição da síntese protéica. Dados prévios do nosso laboratório sugerem que PKR está envolvida na hiperalgesia térmica de origem inflamatória. No presente estudo, foi investigado o papel da PKR na hiperalgesia térmica induzida pelo vírus da herpes simples tipo 1 (HSV1), durante as fases herpética e pós-herpética, combinando métodos comportamentais, genéticos, farmacológicos e moleculares. Camundongos C57bl/6, PKR+/+ e PKR-/- machos foram inoculados com HSV1. Os grupos controle foram inoculados com HSV1 inativo. Alodínia mecânica e hiperalgesia térmica foram monitoradas antes da inoculação do vírus e 8, 14, 21 e 28 dias após a inoculação. A curva dose e temporesposta e o teste da capsaicina foram realizados no 8º e 21º dias após a inoculação do vírus. Também nos períodos herpético e pós-herpético, foi investigado o perfil de expressão de proteínas envolvidas nas vias de sinalização de PKR (PKR, eIF2?, PACT, IKK e PP2A?), assim como o efeito da inibição de PKR pelo monitoramento da fosforilação de PKR, IKK?/?, P38, JNK, ERK1,2 e STAT3, e expressão de CaMKII? e TRPV1 nos GRD (L3-L6) ipsilateralmente à pata inoculada. Alodínia mecânica e hiperalgesia térmica ficaram evidentes até 28 dias após a inoculação. Camundongos PKR-/- desenvolveram alodínia mecânica, mas não hiperalgesia térmica, quando comparados com animais PKR+/+. A inibição sistêmica de PKR reverteu a hiperalgesia térmica de modo tempo- e dose-dependente e preveniu o comportamento nocifensivo induzido por capsaicina, enquanto PKR-/- apresentaram resposta nocifensiva praticamente ausente em ambas as fases herpética e pósherpética. Houve aumento da expressão de PP2A? e da fosforilação de PKR, IKK?/? e eIF2?, durante os períodos herpético e pós-herpético, e de PACT na fase pósherpética. A inibição de PKR promoveu o aumento da fosforilação de P38 em ambas as fases, e redução da fosforilação de PLC?1 acompanhada do retorno da fosforilação de Akt e STAT3 ao nível do grupo controle e o aumento da expressão de Ca-MKII? na fase herpética. Já na fase pós-herpética, reduziu a fosforilação de JNK e Akt e a expressão de Ca-MKII?, retornou a fosforilação de ERK1,2, PLC?1 e STAT3 ao nível do grupo controle e aumentou a expressão de TRPV1. Nossos resultados indicam que a atividade de PKR desempenha papel essencial na hiperalgesia térmica induzida por infecção pelo HSV1 / Double stranded RNA-activated protein kinase (PKR) is a sentinel molecule activated by cellular stress conditions, including viral infections. PKR activation by phosphorylation triggers cascades involved in inflammatory response and protein synthesis suppression. Our previous data suggest that PKR is involved in the inflammatory thermal hyperalgesia. Here we investigated the role played by PKR on thermal hyperalgesia induced by herpes simplex virus type-1 (HSV-1), during herpetic and post-herpetic phases, by combining behavioral, genetic, pharmacological, and molecular methods. Adult male C57bl/6, PKR+/+ and PKR-/- mice were inoculated with HSV-1. Control groups were inoculated with inactive (mock) HSV1. Mechanical allodynia and thermal hyperalgesia were monitored before virus inoculation and 8, 14, 21, and 28 days post-inoculation. The dose- and timeresponse curve and the capsaicin test were performed at 8th and 21st days post virus inoculation. Also in the herpetic and post-herpetic periods, was investigated the expression profile of proteins involved in the PKR signaling pathways (PKR, eIF2?, PACT, IKK and PP2A?), and the effect of PKR inhibition by monitoring PKR, IKK?/?, P38, JNK, ERK1,2, and STAT3 phosphorylation, and Ca-MKII? and TRPV1 expression in the dorsal root ganglia (L3-L6) ipsilaterally to the inoculated paw. Mechanical allodynia and thermal hyperalgesia became evident until 28 days postinnoculation. PKR-/- mice developed mechanical allodynia but not thermal hyperalgesia, when compared with PKR+/+ mice. Systemic PKR inhibition reversed thermal hyperalgesia in a dose and time-dependent manner, and prevented the capsaicin-induced nocifensive behavior, whereas PKR-/- showed no nocifensive behavior almost absent in both herpetic and post-herpetic phases. There was increased expression of PP2A? and the phosphorylation of PKR, IKK?/?, and eIF2?, during herpetic and post-herpetic periods, and PACT in the post-herpetic phase. PKR inhibition increased P38 phosphorylation in both phases, and reduction of PLC?1 phosphorylation together with the return of the Akt and STAT3 phosphorylation to the control group level, and enhanced Ca-MKII? expression in the herpetic phase. At the post-herpetic phase, suppressed JNK and Akt, and Ca-MKII? expression returned ERK1,2, PLC?1 and STAT3 phosphorylation to control group level and increased TRPV1 expression. The data indicate that PKR activity plays an essential role in the HSV-1 infection-induced thermal hyperalgesia

Chronic pain

Dor crônica

Herpes simplex virus type-1

Herpetic neuralgia

Neuralgia herpética

Neuralgia pós-herpética

Neuropatia periférica

Peripheral neuropathy

PKR

PKR

Post-herpetic neuralgia

Vírus herpes simples tipo 1

Atividade da proteína quinase dependente de RNA (PKR) no sistema nociceptivo em um modelo experimental de neuropatia periférica de origem viral / Double stranded RNA-activated protein kinase (PKR) activity in the nociceptive system in an experimental model of peripheral neuropathy of viral origin

Clarissa Maria Dias Mota

25 February 2016

A proteína quinase dependente de RNA (PKR) é uma molécula sentinela ativada em situações de estresse celular, incluindo infecções virais. A ativação de PKR por meio de sua fosforilação aciona cascatas de sinalização intracelular envolvidas em respostas inflamatórias e inibição da síntese protéica. Dados prévios do nosso laboratório sugerem que PKR está envolvida na hiperalgesia térmica de origem inflamatória. No presente estudo, foi investigado o papel da PKR na hiperalgesia térmica induzida pelo vírus da herpes simples tipo 1 (HSV1), durante as fases herpética e pós-herpética, combinando métodos comportamentais, genéticos, farmacológicos e moleculares. Camundongos C57bl/6, PKR+/+ e PKR-/- machos foram inoculados com HSV1. Os grupos controle foram inoculados com HSV1 inativo. Alodínia mecânica e hiperalgesia térmica foram monitoradas antes da inoculação do vírus e 8, 14, 21 e 28 dias após a inoculação. A curva dose e temporesposta e o teste da capsaicina foram realizados no 8º e 21º dias após a inoculação do vírus. Também nos períodos herpético e pós-herpético, foi investigado o perfil de expressão de proteínas envolvidas nas vias de sinalização de PKR (PKR, eIF2?, PACT, IKK e PP2A?), assim como o efeito da inibição de PKR pelo monitoramento da fosforilação de PKR, IKK?/?, P38, JNK, ERK1,2 e STAT3, e expressão de CaMKII? e TRPV1 nos GRD (L3-L6) ipsilateralmente à pata inoculada. Alodínia mecânica e hiperalgesia térmica ficaram evidentes até 28 dias após a inoculação. Camundongos PKR-/- desenvolveram alodínia mecânica, mas não hiperalgesia térmica, quando comparados com animais PKR+/+. A inibição sistêmica de PKR reverteu a hiperalgesia térmica de modo tempo- e dose-dependente e preveniu o comportamento nocifensivo induzido por capsaicina, enquanto PKR-/- apresentaram resposta nocifensiva praticamente ausente em ambas as fases herpética e pósherpética. Houve aumento da expressão de PP2A? e da fosforilação de PKR, IKK?/? e eIF2?, durante os períodos herpético e pós-herpético, e de PACT na fase pósherpética. A inibição de PKR promoveu o aumento da fosforilação de P38 em ambas as fases, e redução da fosforilação de PLC?1 acompanhada do retorno da fosforilação de Akt e STAT3 ao nível do grupo controle e o aumento da expressão de Ca-MKII? na fase herpética. Já na fase pós-herpética, reduziu a fosforilação de JNK e Akt e a expressão de Ca-MKII?, retornou a fosforilação de ERK1,2, PLC?1 e STAT3 ao nível do grupo controle e aumentou a expressão de TRPV1. Nossos resultados indicam que a atividade de PKR desempenha papel essencial na hiperalgesia térmica induzida por infecção pelo HSV1 / Double stranded RNA-activated protein kinase (PKR) is a sentinel molecule activated by cellular stress conditions, including viral infections. PKR activation by phosphorylation triggers cascades involved in inflammatory response and protein synthesis suppression. Our previous data suggest that PKR is involved in the inflammatory thermal hyperalgesia. Here we investigated the role played by PKR on thermal hyperalgesia induced by herpes simplex virus type-1 (HSV-1), during herpetic and post-herpetic phases, by combining behavioral, genetic, pharmacological, and molecular methods. Adult male C57bl/6, PKR+/+ and PKR-/- mice were inoculated with HSV-1. Control groups were inoculated with inactive (mock) HSV1. Mechanical allodynia and thermal hyperalgesia were monitored before virus inoculation and 8, 14, 21, and 28 days post-inoculation. The dose- and timeresponse curve and the capsaicin test were performed at 8th and 21st days post virus inoculation. Also in the herpetic and post-herpetic periods, was investigated the expression profile of proteins involved in the PKR signaling pathways (PKR, eIF2?, PACT, IKK and PP2A?), and the effect of PKR inhibition by monitoring PKR, IKK?/?, P38, JNK, ERK1,2, and STAT3 phosphorylation, and Ca-MKII? and TRPV1 expression in the dorsal root ganglia (L3-L6) ipsilaterally to the inoculated paw. Mechanical allodynia and thermal hyperalgesia became evident until 28 days postinnoculation. PKR-/- mice developed mechanical allodynia but not thermal hyperalgesia, when compared with PKR+/+ mice. Systemic PKR inhibition reversed thermal hyperalgesia in a dose and time-dependent manner, and prevented the capsaicin-induced nocifensive behavior, whereas PKR-/- showed no nocifensive behavior almost absent in both herpetic and post-herpetic phases. There was increased expression of PP2A? and the phosphorylation of PKR, IKK?/?, and eIF2?, during herpetic and post-herpetic periods, and PACT in the post-herpetic phase. PKR inhibition increased P38 phosphorylation in both phases, and reduction of PLC?1 phosphorylation together with the return of the Akt and STAT3 phosphorylation to the control group level, and enhanced Ca-MKII? expression in the herpetic phase. At the post-herpetic phase, suppressed JNK and Akt, and Ca-MKII? expression returned ERK1,2, PLC?1 and STAT3 phosphorylation to control group level and increased TRPV1 expression. The data indicate that PKR activity plays an essential role in the HSV-1 infection-induced thermal hyperalgesia

Dor crônica

Neuralgia herpética

Neuralgia pós-herpética

Neuropatia periférica

PKR

Vírus herpes simples tipo 1

Chronic pain

Herpes simplex virus type-1

Herpetic neuralgia

Peripheral neuropathy

PKR

Post-herpetic neuralgia

Analysis and Modulation of PACT, DICER and MBNL1 in the Context of Myotonic Dystrophy Type I

Azimi, Mehrdad

January 2016

Myotonic Dystrophy Type I (DM1) is a multi-systemic genetic neuromuscular degenerative disease, has a prevalence in most populations of about 1:8000 and is caused by the nuclear retention of pathogenically expanded DMPK mRNA. A previous DM1 RNAi-kinome screen in our lab has identified kinases that reduced both count and area of DMPK mRNA foci in vitro. One such discovered kinase is PACT, which has showed to decrease foci count and area in DM1 fibroblasts by 30-50%. This study explored PACT as well as binding partner DICER involved in cellular RNA processing machinery, to highlight potential therapeutic targets in DM1. DM1 fibroblasts treated with PACT siRNA showed a non-significant trend of upregulation in MBNL1 mRNA and protein expression. PACT knockdown also showed trend of missplicing normalization in SERCA-1, more prominently seen in DM1-2000 human fibroblasts, whereas IR (insulin receptor) splicing remained unaffected. On the other hand, DICER knockdown did not have profound affect on foci integrity as well as MBNL1 RNA and protein xpressions in DM1 fibroblasts. SERCA-1 splicing in DICER siRNA treated samples also remained unchanged. We report here our findings in pursuit of potential therapeutic targets for the treatment of DM1.

Myotonic Dystrophy Type I

DM1

PACT

DICER

TRBP

miRNA

PKR

Alternative splicing

Nuclear foci

MBNL1

DMPK

SERCA1

Insulin receptor

RISC

The impact of the integrated stress response on DNA replication

Choo, Josephine Ann Mun Yee

12 December 2019

No description available.

570

Integrated stress response

PKR

PERK

GCN2

eIF2alpha

R-loops

DNA replication

DNA fiber assays

Biologie (PPN619462639)