AN INVESTIGATION ON THE EFFECTS OF INFLUENZA VIRUS INFECTION AS IT PERTAINS TO THE INITIATION OF TRANSLATION

McCoy, Morgan Hager

01 January 2004

Like the majority of host cell mRNAs, the mRNAs of influenza virus are capped and polyadenylated. The NS1 protein of influenza has been implicated as a translational activator for both influenza and reporter gene mRNAs. Data is presented showing that influenza A virus infection resulted in an increased ratio of cap-dependent to cap-independent translation. This ratio increase was largely due to an increase in cap-dependent translation. These experiments employed a bicistronic reporter construct measuring cap-dependent and cap-independent translation in a single sample. Expression of NS1 alone resulted in a small, but reproducible increase in the ratio of cap-dependent to cap-independent translation. Additionally, with use of an NS1 deleted mutant influenza A virus (delNS1) it is shown that infection without NS1 expression produced less of a translation ratio increase compared to wild-type virus infection. Furthermore, expression of NS1 rescued a more wild-type ratio increase in delNS1 infected Vero cells. These results implicate NS1 as playing a role in increasing the ratio of cap-dependent to cap-independent translation in influenza A virus infected cells. Additionally, eIF4E-binding protein-1 (4E-BP1), a member of the protein family that inhibits cap-dependent translation through their inhibition of the cap-binding protein, eukaryotic initiation factor 4E (eIF4E), is shown to be inactivated throughout the majority of the influenza A virus infection process.

Molecular mechanisms of programmed ribosomal frameshifting and cap-independent translation of Dianthovirus / ダイアンソウイルスのフレームシフト翻訳とキャップ非依存的翻訳の分子機構

Tajima, Yuri

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第18334号 / 農博第2059号 / 新制||農||1023(附属図書館) / 学位論文||H26||N4841(農学部図書室) / 31192 / 京都大学大学院農学研究科応用生物科学専攻 / (主査)教授 奥野 哲郎, 教授 佐久間 正幸, 准教授 吉田 天士 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

plant virus

cap-independent translation

ribosomal frameshifting

Dianthovirus

610

Biophysical Characterization of Protein-RNA Interactions Regulating Cap-Independent Translation in Enterovirus 71

Tolbert, Michele M.

07 September 2017

No description available.

Chemistry

Biochemistry

Biophysics

Cap-Independent Translation

EV71

RNA Structure

Objasnění vlivu proteinkináz ERK1 a ERK2 na iniciaci translace nezávislé na čepičce / Elucidation of ERK1 and ERK2 protein kinases effect on cap-independent translation initiation

Přibyl, Miroslav

January 2016

Protein kinases ERK1 and ERK2 are one of the most studied proteins in cell signalling. Both proteins are involved in a plethora of processes, such as phosphorylation and activation of kinases as part of signalling pathways. Enzymes ERK1 and ERK2 are part of MAPK/ERK signalling cascade, connected to many cellular including cell proliferation, cell growth or differentiation. The MAPK/ERK signalling cascade is often activated in different types of tumors, making it a candidate for developing new chemical inhibitors. One of the important questions in fundamental research of ERK1 and ERK2 protein kinases is the search for difference between these proteins. Current knowledge points to redundancy of both proteins, howver several examples suggest otherwise. Recently, the work presented in Casanova et al. 2012 indirectly suggests divergent effect of ERK1 and ERK2 on cap-independent translation initiation. In the Laboratory of RNA biochemistry we focus on HCV IRES (Hepatitis C Virus Internal Ribosome Entry Site) dependent translation initiation. This diploma thesis lead to establish RNA interference method in our laboratory and to establish reporter system to study ERK1 and ERK2 effect on HCV IRES dependent translation initiation. Based on our data acquired during our research, we present in this work...

Multiple Recoding Mechanisms Produce Cyclooxygenase and Cyclooxygenase-Related Proteins from Frameshift-Containing COX-3/COX-1b Transcripts in Rat and Human

Hunter, John Cameron

08 August 2012

To increase diversity of enzymes and proteins, cells mix and match exonic and intronic regions retained in mature mRNAs by alternative splicing. An estimated 94% of all multi-exon genes express one or more alternatively spliced transcripts generating proteins with similar or modified functions. Cyclooxygenase is a signaling enzyme that catalyzes the rate-limiting step in the synthesis of diverse bioactive lipids termed prostaglandins. Prostaglandins are involved in myriad physiological and pathopysiological processes including vasoregulation, stomach mucosal maintenance, parturition, pain, fever, inflammation, neoplasia and angiogenesis and are inhibited by aspirin-like drugs known as NSAIDs. In 2002 an alternatively spliced, intron-1 retaining variant of COX-1 was cloned from canine brain tissue. This new variant, termed COX-3 or COX-1b, is an enzymatically active prostaglandin synthase expressed at relatively high levels in a tissue and cell type dependant manner in all species examined. In humans and most rodent species intron-1 is 94 and 98 nucleotides long respectively. Retention of the intron in these species introduces a frameshift and is predicted to result in translation of a very small 8-16kD protein with little similarity to either 72kD COX-1 or COX-2, calling into question the role of this variant. In this dissertation, I present my results from cloning and ectopically expressing a complete and accurate COX-3 cDNA from both rat and human. I confirmed that COX-3 mRNA encodes multiple large molecular weight cyclooxygenase-like proteins in the same reading frame as COX-1. Translation of these proteins relies on several recoding mechanisms including cap-independent translation initiation, alternative start site selection, and ribosomal frameshifting. Using siRNA and Western blotting I have identified some of these proteins in tissues and cells. Two COX-3 encoded proteins are active prostaglandin synthase enzymes with activities similar to COX-1 and represent novel targets of NSAIDs. Other COX-3 proteins have unknown function, but their size and cellular location suggest potential roles as diverse as cytosolic enzymes and nuclear factors.

Cyclooxygenase

COX-3

Prostaglandins

Alternative Splicing

Ribosomal frameshift

Cap-independent translation

Chemistry

Defining the Structural Modulation of Cap-Independent Translation in Enterovirus 71

Dávila-Calderón, Jesse

23 May 2022

No description available.

Chemistry

Biophysics

Virology

Enterovirus 71

Cap-independent translation

RNA virus

biophysics

structural biology

Investigation of cap-independent translation in neuronal differentiation

Ruhe, Larissa

15 June 2020

Initiation der Translation ist ein komplexer und stark regulierter Prozess, bei dem Ribosomen die mRNA binden. Die überwiegende Mehrheit eukaryotischer mRNAs wird durch einen 5‘-Cap-abhängigen Mechanismus translatiert. Dazu bindet der eIF4F-Proteinkomplex die mRNA an der 5'-Cap-Struktur, um weitere eIFs und die kleine ribosomale Untereinheit zu rekrutieren, welche dann die 5'UTR von 5'- in 3'-Richtung bis zu einem Startcodon scannt. Anschließend trifft die große ribosomale Untereinheit dazu und die Proteinsynthese beginnt. Darüber hinaus kann die Translation durch IRES, interne ribosomale Eintrittsstellen, vermittelt werden, welche das Ribosom unabhängig von Cap und 5‘-Ende zum Startcodon rekrutieren. Die zelluläre IRES-vermittelte Translation gilt als ineffizient unter physiologischen Bedingungen, wird aber durch Stress aktiviert. Da die Regulation dieses Mechanismus weitaus unbekannt ist, haben wir die zelluläre, Cap-unabhängige Translationsinitiation untersucht. Dafür haben wir eine embryonale Stammzelllinie generiert, welche eine dominant-negative Mutante von 4E-BP1 exprimiert. 4E-BP1 bindet das 5‘-Cap-bindende Protein, sodass eIF4F nicht am 5'-Cap andocken kann. Wir haben das Proteom während der Überexpression von 4E-BP1 und der neuronalen Differenzierung bestimmt, um Translationsdynamiken systemisch zu erfassen. Gene mit verminderter Sensitivität für die Cap-abhängige Translation wurden so identifiziert und in bicistronischen Reporter-Assays getestet. Nach strenger Validierung wurde eine Cap-unabhängig translatierte mRNA, Pqbp1, entdeckt. Der zweite Teil dieser Studie untersuchte die Cap-unabhängige Translation einer circRNA, welche keine freien Enden hat und daher per IRES translatiert werden muss. Wir konnten bestätigen, dass circMbl in vitro translatiert wird und konnten so innerhalb eines Kooperationsprojekts zu der Erkenntnis beitragen, dass circRNAs im Fliegengehirn translatiert werden. / Translation initiation is a complex and highly regulated process which involves the assembly of an elongation competent ribosome on the mRNA. The vast majority of eukaryotic mRNAs is translated by a canonical cap-dependent mechanism. This requires the eIF4F protein complex to bind the mRNA at the 5’-cap to recruit further eIFs and the small ribosomal subunit which then scans the 5’UTR in 5’ to 3’ direction until a start codon is encountered. Afterwards the large ribosomal subunit joins and protein synthesis begins. Besides that, translation of mRNAs can be mediated by IRESs, internal ribosome entry sites, which recruit the ribosome in a cap and 5’-end-independent manner to the start codon. Such cellular IRES-mediated translation is thought to be inefficient under physiological conditions but activated during stress. As the regulation of this mechanism is not well understood, we aimed to elucidate cellular cap-independent translation events. Therefore, we generated a mouse embryonic stem cell line with inducible overexpression of a dominant negative mutant of 4E-BP1. 4E-BP1 sequesters the cap-binding protein eIF4E so that the eIF4F protein complex fails to assemble at the 5’-cap. We performed shotgun proteomics during 4E‑BP1 overexpression and neuronal differentiation to globally monitor translation dynamics. Genes with reduced sensitivity for cap-dependent translation were identified and tested for internal translation initiation in bicistronic reporter assays. After stringent validation one cap-independently translated mRNA, Pqbp1, was discovered. The second part of this study investigated cap-independent translation initiation on a circRNA, which by nature lacks free ends and thus requires IRES-mediated translation. We could show that circMbl is translated in vitro and thus contributed to the scientific evidence for the translation of circRNAs in fly brain, which was studied in a collaboration project.

zelluläre IRES

5' Cap-unabhängige Translation

Translationsinitiation

circRNA

cap-independent translation

cap-dependence

cellular IRES

translational control

bicistronic vector

translation initiation

circRNA

circRNA translation

bicistronic reporter assay

570 Biologie

WD 5355

WG 1900

WE 4100

WX 6501

WW 3800

ddc:570