Translation of Hepatitis A Virus IRES Is Upregulated by a Hepatic Cell-Specific Factor / A型肝炎ウイルスIRES依存的翻訳は肝臓特異的因子により活性化される

Sadahiro, Akitoshi

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第21654号 / 医博第4460号 / 新制||医||1035(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 朝長 啓造, 教授 妹尾 浩, 教授 萩原 正敏 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Hepatitis A virus (HAV)

internal ribosome entry site (IRES)

translation regulation

translation initiation

tropism

490

Mechanisms of Post-transcriptional Regulation of Cat-1 Gene Expression by Amino Acid Starvation

Yaman, Ibrahim

05 July 2005

No description available.

Health Sciences, Nutrition

AU-rich element

mRNA stability

translational control

IRES

amino acid starvation

ITAF

NOVEL TRANSLATIONAL REGULATION OF THE PROAPOPTOTIC BCL2 MEMBER PUMA AND ITS ROLE DURING SKELETAL MYOBLAST APOPTOSIS

Shaltouki, Atossa

06 April 2011

No description available.

Cellular Biology

PUMA

Apoptosis

Translation

mRNA

IRES

Skeletal Myoblast

Differentiation

Total Protein Synthesis

Investigation into Catalytic Metallodrugs that Target Hepatitis C IRES RNA: Development, Characterization, and Mechanism

Ross, Martin James

January 2015

No description available.

Chemistry

RNA oxidation

ATCUN

SLIIb

SLIV

HCV

IRES

5 NTR

Cu

Ni

Pd

Pt

Au

Co

Hledání lidských bílkovin ovlivňujících funkci IRES viru hepatitidy typu C / Screening for the HCV IRES interacting proteins

Roučová, Kristina

January 2012

Hepatitis C virus (HCV) is a worldwide spread pathogen infecting up to 3 % of the human population. Nowadays, research of new drugs against this virus is focused on the individual steps in its life cycle, including the translation initiation. In the case of HCV translation initiation is dependent on the internal ribosome entry site (IRES). Besides of components of the translational machinery also other components of the cell, so called IRES trans-acting factors (ITAF), contribute to its proper progress. This work continues in previous research of our laboratory focused on searching for new ITAF. In order to search for potential ITAF increasing HCV IRES activity new recombinant plasmid vectors and reference strains were prepared and selection conditions of the selection system were optimized. The differences in the growth characteristics of the reference strains were analyzed and quantified under selective and non-selective conditions. A set of pilot high efficiency transformations of the yeast strain pJ69-4A carrying bicistronic construct with HCV IRES were conducted using human expression cDNA library in order to optimize the efficiency of transformation and selection conditions and to attempt to identify new ITAF. Several dozens of randomly selected clones from these transformations obtained under...

Functional Characterization Of The Internal Ribosome Entry Site Of Coxsackievirus B3 RNA

Verma, Bhupendra Kumar

04 1900

CoxsackievirusB3 (CVB3), a member of the Picornaviridae family is the causative agent of Virus-induced Myocarditis and Dilated Cardiomyopathy. The 5’UTR contains an Internal Ribosome Entry Site or IRES element that recruits ribosomes in a cap-independent manner. The ribosomes are recruited upstream of the AUG triplet at 591 (AUG591), also called as the cryptic AUG, after which they scan downstream for about 150 nucleotide, before initiating at the initiator AUG or AUG741. The 3’UTR of CVB3 is 99 nts long, highly structured RNA containing conserved domains, and is followed by a poly (A) tail of variable lengths. We have investigated possible involvement of host proteins which may interact with CVB3 IRES and influence its activity. We have demonstrated the role of Poly-pyrimidine tract binding protein (PTB) and established PTB as a bona-fide ITAF for CVB3, by characterizing the effect of partial silencing of PTB ex-vivo in HeLa cells. The IRES activity in BSC-1 cells, reported to have very low level of endogenous PTB, is found to be significantly low compared to that in HeLa cells. PTB is observed to interact with both the 5’ and 3’ UTR of CVB3, although with different affinities. Finer mapping of the interaction between PTB and the UTRs showed that the protein interacts with multiple regions of both UTRs. We have also shown the cis-acting effect of the CVB3-3’UTR on IRES mediated translation. The PTB contact points on the 3’UTRwas found to map to conserved regions, the deletion of which abrogates the 3’UTR mediated enhancement of the IRES activity. The possible role played by PTB in enhancing IRES activity by CVB3 3’UTR suggests that PTB protein might help in circularization of the CVB3 RNA by bridging the ends necessary for efficient translation of the viral RNA. In the second part, we have investigated possible role of some of the cis-acting element present in the CVB3 5’UTR RNA particularly the cryptic AUG. We have shown that mutation in cryptic AUG reduces the efficiency of translation mediated by the CVB3 IRES. Mutation in cryptic AUG moiety also reduces the interaction of mutant RNA with La protein. We have demonstrated that binding of 48S ribosomal complex with mutant IRES RNA was weaker compared to wt IRES RNA. We have investigated the possible alteration in secondary structure in the mutant RNA by chemical and enzymatic modification, which suggests that there is marginal alteration in the local structure due to mutation. It appears that integrity of cryptic AUG is important for efficient translation initiation by the CVB3 IRES. Results suggest that cryptic AUG plays a significant role in mediating internal initiation of translation of CVB3 RNA by mediating precise La binding and correct positioning of the 48S ribosomal complex. Finally, we have investigated the importance of a conserved hexa-nucleotide stretch in the apical loop within stem loop C (SLC, nt104-180), upstream of the ribosome landing site, on CVB3 IRES function. It has been already shown from our laboratory that the deletion at this apical loop resulted in significant decrease in IRES activity. This deletion mutant was shown to alter the secondary structure of the CVB3 5’UTR RNA. Here we have investigated the effect of point mutation in the apical loop SLC/c on CVB3 IRES activity by generating substitution mutation in the apical loop SLC/c in order to avoid possible alteration in secondary structure. Both the deletion or substitution mutation at this apical loop resulted in significant decrease in IRES activity. Both the mutant IRES RNAs (deletion and substitution mutant) failed to interact with certain trans-acting factors. Furthermore, expression of CVB3 2A protease significantly enhanced IRES activity of the wild type, but the effect was not so pronounced on the mutant IRESs. It is possible that the mutant RNAs were unable to interact with some trans-acting factors critical for enhanced IRES function. We have short-listed three proteins of approximate molecular mass of 56, 64 and 90 kDa, which showed reduced binding with mutant IRESs. By using RNA affinity column with biotinylated UTP labeled RNA we have purified couple of proteins and identified p64 as Cyto Keratin 1 protein by performing in-gel trypsin digestion followed by MALDI analysis. Overall, the results characterize the CVB3 IRES structurally and functionally, which could be useful in targeting critical RNA-protein interactions to develop candidate antiviral agent against Coxsackievirus infection.

Ribosomes

Coxsackievirus B3

Ribonucleic Acid (RNA)

RNA Viruses

Internal Ribosome Entry Site (IRES)

Coxsackievirus B3 - Translation

Viruses - Reproduction

IRES Mediated Translation

Viral Proteins

Coxsackievirus B3 RNA Translation

CVB3

Cryptic AUG

Biochemical Genetics

Studie rozmanitosti HCV IRES: propojení experimentálního přístupu s přípravou a hodnocením rozsáhlé databáze mutací / A study of the HCV IRES variability: An experimental approach coupled with design of a large-scale mutation database

Khawaja, Anas Ahmad

January 2016

Translation initiation in the hepatitis C virus (HCV) occurs through a cap- independent mechanism that involves an internal ribosome entry site (IRES) capable of interaction with and utilization of the eukaryotic translational machinery. We focused on the structural configuration of the different HCV-IRES domains and the impact of IRES primary sequence variations on secondary structure conservation and function. For this purpose we introduced into our laboratory, methods such as denaturing gradient and temperature gradient gel electrophoresis for screening the degree of heterogeneity and total amount of HCV-IRES variability accumulated in HCV infected patients over a period of time. The selected samples showed variable migration pattern of the HCV-IRES (from all the patients) visualized in DGGE and TGGE, were sequenced and evaluated for translation efficiency using flow cytometry. In some cases, we discovered that multiple mutations, even those scattered across different domains of HCV-IRES, led to restoration of the HCV-IRES translational activity, although the individual occurrences of these mutations were found to be deleterious. We propose that such observation may be attributed to probable long- range inter- and/or intra-domain functional interactions. We established a large-scale HCV-IRES...

Structural insights into noncanonical mechanisms of translation

James, Nathan Rhys

January 2017

Translation is the process by which proteins are synthesized from the instructions in the genetic code. Translation is mediated by the ribosome, a large ribonucleoprotein complex, in concert with messenger RNA (mRNA), transfer RNA (tRNA), and a variety of proteins. The canonical mechanism of translation, introduced in Part I of my thesis, is divided into four distinct phases: initiation, elongation, termination, and recycling. Under unusual circumstances, each phase of translation can also proceed via a number of noncanonical mechanisms, many of which are vitally important for cellular growth or viral infectivity. My thesis describes structural insights into two such noncanonical mechanisms. The aim of the first project, described in Part II, was to structurally characterize a noncanonical mechanism of translational termination in bacteria. In the absence of a stop codon, ribosomes arrest at the 3′ end of an mRNA and are unable to terminate. In bacteria, the primary mechanism for rescuing such nonstop complexes is known as trans-translation. In the absence of a functional trans-translation system, however, the small protein ArfA recognizes the empty mRNA channel and recruits the release factor RF2 to the ribosome, enabling termination to occur. Using single-particle electron cryomicroscopy (cryo-EM), I obtained four high-resolution structures of nonstop complexes that reveal the mechanism of ArfA-mediated ribosome rescue and have wider implications for understanding canonical termination in bacteria. The aim of the second project, described in Part III, was to gain structural insights into a noncanonical mechanism of translational initiation in eukaryotes known as internal ribosome entry. Instead of a 5′ cap, many viruses contain intricately structured, cis-acting internal-ribosome-entry sites (IRESs) within their genomes that direct end-independent initiation. The IRES of hepatitis-C virus (HCV), for example, interacts directly with the mammalian ribosome and functionally replaces many of the canonical initiation factors. However, the mechanism by which the HCV IRES coordinates assembly of an initiation complex and progresses through the initiation phase remains poorly understood. I developed a method for purifying native ribosomal complexes from cell lysate that enabled me to obtain multiple cryo-EM maps of the HCV IRES in complex with the 80S ribosome, including a previously unseen conformation of the IRES induced by rotation of the ribosomal small subunit, and to make progress towards capturing earlier steps in the initiation pathway.

572.8

Functional Analyses of West Nile Virus (WNV) Bicistronic Replicons Containing Different Sequence Elements and of Simian Hemorrhagic Fever Virus (SHFV) Polyprotein Processing

Radu, Gertrud Ulrike

29 November 2007

The flavivirus West Nile virus (WNV) encodes a single polyprotein that is processed into three structural and seven nonstructural proteins. Various WNV bicistronic replicons that direct cap-dependent translation of an N-terminal viral capsid or capsid/Renilla luciferase fusion protein as well as IRES-dependent translation of the nonstructural proteins were constructed. An original replicon consisting of the WNV 5' NCR, the 5' 198 nts of the capsid coding sequence, which included the 5' cyclization sequence (Cyc), and an EMCV IRES followed by the WNV nonstructural genes and 3' NCR was generated. Real time qRT-PCR analysis of intracellular levels of this replicon RNA showed a 4 fold increase by 96 hr after transfection of BHK cells. Increasing the distance between the 5' Cyc and IRES by insertion of a 5' IRES flanking sequence alone or together with a Renilla luciferase reporter did not increase RNA replication. Addition of only a reporter decreased RNA replication. The insertion of an extended capsid coding sequence also did not enhance RNA replication, but did enhance both cap- and IRES-dependent translation of replicon RNA, as indicated by immunofluorescence and Western blot analysis. These results suggest the presence of a translation enhancer in the 3' portion of the capsid coding region. Simian hemorrhagic fever virus (SHFV) is a member of the family Arteriviridae, order Nidovirales. SHFV is unique among Nidoviruses in having three instead of two papain-like cysteine protease (PCP) motifs designated alpha, beta, and gamma, within the N-terminal region of its ORF1a. Mutations of putative PCP cleavage sites showed that the most efficient cleavage was by PCP beta at its downstream cleavage site. A large deletion located between the two catalytic residues of PCP alpha was hypothesized to render this protease inactive. However, processing was observed at the cleavage site following PCP alpha. Mutational analyses confirmed that PCP alpha is an inactive protease, and that the cleavage sites downstream of PCP alpha are cleaved by PCP gamma. When the catalytic residues of PCP gamma were mutated, PCP beta was also able to back cleave at these sites. This "back" cleavage is a previously unreported activity for an arterivirus PCP.

Papain-like cysteine protease

West Nile virus

IRES

Capsid

Simian hemorrhagic fever virus

Translation

RNA Replication

Replicon

Biology, general

Etude des mécanismes moléculaires de l'initiation de la traduction de l'ARN génomique du VIH-1 / Molecular mechanisms of translation initiation of the genomic RNA of HIV-1

Deforges, Jules

27 March 2014

L’ARN génomique du virus de l’immunodéficience humaine de type 1 (VIH-1) est multifonctionnel et suit au moins deux destins. Soit il est traduit par la machinerie traductionnelle de l’hôte donnant naissance aux polyprotéines Gag et Gag-pol, soit il se dimérise et est encapsidé dans les virions en tant que génome viral. Les travaux du laboratoire visent à identifier les mécanismes moléculaires de la traduction de l’ARN génomique et de sa dimérisation, ainsi que les déterminants gouvernant la balance entre ces deux phénomènes. La traduction de l’ARN génomique viral peut être initiée de trois façons. Selon le mécanisme canonique nécessitant la présence d’une coiffe à l’extrémité 5’ de l’ARN, et grâce à deux sites d’initiation par entrée interne des ribosomes (IRES). Un IRES a été mis en évidence dans la 5’ UTR, dont l’activité est stimulée lors en phase G2/M du cycle cellulaire uniquement. Un second IRES a été découvert dans la région codante de gag. Il est capable de lier directement la petite sous-unité ribosome et le facteur d’initiation eIF3, et permet l’initiation à partir de deux codons AUG situés dans la même phase de lecture, conduisant à la synthèse d’une isoforme additionnelle de Gag. Mon projet de thèse a consisté en l’étude de l’influence de la structure secondaire sur la traduction et la dimérisation. Dans un premier temps, j’ai mis en place au laboratoire une nouvelle technique de sondage de structure, appelée « SHAPE », développée par le laboratoire de K. Weeks. Le SHAPE nous permet désormais de sonder rapidement la structure secondaire de nombreux ARN, et notamment de tester en routine l’effet de mutations sur la structure secondaire. Cette technique a permis d’étudier la structure secondaire de la 5’ UTR dans différentes conditions. Nous avons ainsi identifié une signature de la conformation monomère de la 5 UTR, et découvert un nouvel élément impliqué dans la dimérisation in vitro. Par ailleurs, nous avons montré que des extraits de cellules Hela synchronisées en phase G2/M du cycle cellulaire stimulent l’activité de l’IRES de la 5’ UTR et modifient le profil de réactivité de cette région, traduisant probablement une réorganisation structurale induite par le recrutement de protéines cellulaires. Une autre partie de mon projet de thèse a concerné l’étude de l’IRES de la région codante de gag, Des délétions progressives de l’IRES, à partir des extrémités 5’ et 3’ ont mis en évidence l’existence de deux sites de liaison distincts au ribosome, localisés à proximité de chacun des deux codons d’initiation. La délétion de chaque site a permis de confirmer le rôle de la liaison directe au ribosome dans la traduction de gag. L’ensemble de ces éléments nous permet de proposer un modèle moléculaire conduisant à la formation des complexes d’initiation sur chaque codon AUG. Par ailleurs, nos résultats suggèrent qu’une interaction longue-distance entre la boucle PolyA et la région codante de gag régule de la traduction de l’ARN génomique. Un tel mécanisme pourrait permettre de réguler l’efficacité de traduction du gène gag, voire du ratio entre les deux isoformes au cours du cycle réplicatif. / Primate lentiviruses genomic RNA can serve both as an mRNA that encodes for Gag and Gag-Pol polyproteins and as a propagated genome. We previously reported the presence of an IRES activity embedded within Gag coding region itself that drives the production of several isoforms of the Gag polyprotein and that is conserved in HIV-1, HIV-2 and SIVmac. In addition, in vitro reconstitution experiments revealed that the initial step of initiation complex formation is the recruitment of the 40S ribosomal subunit and eIF3. The structural and functional conservation amongst lentiviruses indicates that those properties are important for the virus cycle. In order to define the RNA structural determinants responsible for the formation of IRES/eIF3/40S ternary complex, we have been following functional and biochemical approaches in parallel. Our results indicate that 2 distinct binding sites for the ribosome are present close to the 2 AUG codons used as initiation site for the translation. Further biochemical analyses have shown that 2 ribosomes can be recruited by the same RNA molecule. In order to determine the functional role of the IRES activity on gag translation, we assayed in vitro the translation efficiency of mutants unable to recruit the ribosome. In parallel, we have been following a drug screening strategy to identify small molecules that would inhibit the ribosome recruitment. This approach could pave the way to the definition of the IRESgag as a new therapeutic target, and to the identification of new drugs.

ARN

Traduction

IRES

Initiation ribosome

VIH-1

Structure secondaire

SHAPE

Biologie moléculaire

Dimérisation

Virus

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