Loss of RNA-Binding Protein Sfpq Causes Long-Gene Transcriptopathy in Skeletal Muscle and Severe Muscle Mass Reduction with Metabolic Myopathy / RNA結合タンパク質Sfpqの骨格筋特異的欠損は長鎖遺伝子発現異常と代謝性ミオパチーを伴う重篤な筋量減少を引き起こした

Hosokawa, Motoyasu

23 July 2019

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第22007号 / 医科博第105号 / 新制||科||7(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 稲垣 暢也, 教授 髙橋 良輔, 教授 竹内 理 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

skeletal muscle

RNA binding protein

metabolism

myopathy

long gene

491

Dissecting the multi-functional role of heterogeneous nuclear ribonucleoprotein H1 in methamphetamine addiction traits

Ruan, Qiu T.

24 March 2021

Both genetic and environment factors influence susceptibility to substance use disorders. However, the genetic basis of these disorders is largely unknown. We previously identified Hnrnph1 (heterogeneous nuclear ribonucleoprotein H1) as a quantitative trait gene for reduced methamphetamine (MA) stimulant sensitivity. Mutation (heterozygous deletion of a small region in the first coding exon) in Hnrnph1 also decreased MA reinforcement, reward, and dopamine release. 5’UTR genetic variants in Hnrnph1 support reduced 5’UTR usage and hnRNP H protein expression as a molecular mechanism underlying the reduced MA-induced psychostimulant response. Interestingly, Hnrnph1 mutant mice show a two-fold increase in hnRNP H protein in the striatal synaptosome with no change in whole tissue level. Proteome profiling of the synaptosome identified an increase in mitochondrial complex I and V proteins that rapidly decreased with MA in Hnrnph1 mutants. In contrast, the much lower level of basal mitochondrial proteins in the wild-type mice showed a rapid, MA-induced increase. Altered mitochondrial proteins associated with the Hnrnph1 mutation may contribute to reductions in MA behaviors. hnRNP H1 is an abundant RNA-binding protein in the brain, involved in all aspect of post-transcriptional regulation. We examined both baseline and MA-induced changes in hnRNP H-RNA interactions to identify targets of hnRNP H that could comprise the neurobiological mechanisms of cellular adaptations occurring following MA exposure. hnRNP H post-transcriptionally regulates a set of mRNA transcripts in the striatum involved in psychostimulant-induced synaptic plasticity. MA treatment induced opposite changes in binding of hnRNP H to these mRNA transcripts between Hnrnph1 mutants versus wild-types. RNA-binding, transcriptome, and spliceome analyses triangulated on hnRNP H binding to the 3’UTR of Cacna2d2, an upregulation of Cacna2d2 transcript, and decreased 3’UTR usage of Cacna2d2 in response to MA in the Hnrnph1 mutants. Cacna2d2 codes for a presynaptic, voltage-gated calcium channel subunit that could plausibly regulate MA-induced dopamine release and behavior. The multi-omics datasets point to a dysregulation of mitochondrial function and interrelated calcium signaling as potential mechanisms underlying MA-induced dopamine release and behavior in Hnrnph1 mutants.

Neurobiology

Addiction

Genetics

Methamphetamine

Omics data

RNA binding protein

Splicing

Characterization of the role and regulation of the RNA binding protein HuR in muscle cell differentiation

Van der Giessen, Kate.

January 2007

No description available.

RNA-Binding Proteins.

Muscle Fibers.

Muscle Development -- genetics.

CHARACTERIZATION OF A NEW PUTATIVE ELAV-LIKE BINDING PROTEIN IN ACINETOBACTER BAUMANNII

Ciani, Caterina

06 April 2022

Post-transcriptional regulations (PTRs) have always been considered features of organisms with higher complexity. However recently, the interest toward the post- transcriptional mechanisms in prokaryotes increased. The bacterial proteome is much more complex compared to the genome size, suggesting a tight and articulate regulation of proteins production, extremely important for the bacterial adaptation to an always changing environment. Bacterial PTRs are responsible of modulation of mRNA stability and decay, translation initiation and elongation, modulation of the access of ribosome to the ribosome binding site and control of termination of the transcript. The main actors in the PTRs are small non-coding RNA (responsible of the inhibition of the transcription) and RNA binding proteins (RBPs), which modulate the translation and half-life of the mRNA. RBPs, are particularly of my interest since I wanted to find a possible orthologous of the eukaryotic Elav-like (Elavl) family of proteins in Acinetobacter baumannii. Elav-like proteins are present in all metazoans and are characterized by two highly conserved sequences: RNP-1 (a quite well conserved hexamer) and RNP-2 (a really well conserved octamer) that are responsible of binding to the mRNA. Each species has a different number of Elavl paralogous that is totally independent from the complexity of the organisms, suggesting a more ancient origin. In particular, I focused on the human paralog HuR (human antigen R). HuR is characterized by three RNA Recognition motif (RRM) -domains, is ubiquitously expressed and is mainly localized into the nucleus (where it is responsible of maturation of the mRNA), but under stress stimuli, can shuttle into the cytoplasm where protect the target mRNA from degradation, by binding AU/U rich sequences (ARE sequences). Its high concentration into the cytoplasm can lead to the overexpression of oncogenes and pro-tumorigenic factors. The choice of Acinetobacter baumannii comes from the increasing worldwide concern toward this pathogen that is becoming multidrug resistant. Indeed, in Italy, more the 50% of nosocomial infections are caused by A. baumannii. I found a putative protein (AB-Elavl), composed by a single RRM domain endowed with similar features of the eukaryotic RRM domain as the presence of a quite well conserved RNP-2 and a less conserved RNP-1. I expressed this protein with recombinant tools and confirmed the production of the protein in the host by western blot and mass spectrometry. I evaluated the binding activity of AB-Elavl testing the EC50 and the Kd with different biochemical assays (EMSA, AlphaScreen and HTRF- FRET) toward three different RNA sequences, in order to test the specificity. By X- RAY and NMR, I confirmed the folded structure that can be overlapped to the HuR’s one and the interaction with the probes tested, highlighting the presence of binding, but with different specificity. I also tested some small molecules developed for interfering in the binding of HuR with the target sequence and found a possible compound able to interact with AB-Elavl, by disrupting the binding with the target probe. All these results suggest an ancient origin of the metazoans’ Elavl family of proteins that probably share a common ancestor with AB-Elavl. More studies should be performed to better understand the role of AB-Elavl in A. baumannii as well as in other bacteria. In fact, I found the presence of other ARE sequence-binding proteins also in Pseudomonas aeruginosa. Interesting would be to check the presence of this protein in all the multidrug resistant ESKAPE bacteria.

RRM domain, Elav-like

Biochemical Characterization of Proteins that Interact with RNA

Ye, Xuan

January 2020

No description available.

Biochemistry

Antibacterial Agents: 1,4-Disubstituted 1,2,3-Triazole Analogs of the Oxazolidinone

Acquaah-Harrison, George

20 July 2010

No description available.

Chemistry

Antibacterial agents

Bioisosteric replacement

Analogs of oxazolidinones

RNA binding ligands

Transcription and transport of a messenger RNP particle : novel regulatory mechanisms /

Kylberg, Karin,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 4 uppsatser.

Investigating the mechanism of translational stimulation by Deleted in Azoospermia-like

Smith, Joel W. S.

January 2008

The proper expression of a gene to a protein is a complicated process with many steps. One of the major steps is translation, the process of decoding a messenger RNA signal and the building of a protein from its component parts. The control of translation is one of the major steps for the overall control of gene expression and its dysregulation is associated with a wide variety of human diseases including neurological, metabolic and reproductive disorders. Dazl family proteins are germ cell restricted RNA binding proteins that contain a motif characteristic of this family, the DAZ domain. Whilst humans encode all three family members DAZ, DAZL and BOULE, flies only possess the boule gene. The members of this family have an essential conserved role in gametogenesis in a wide variety of organisms from worm to man with loss of function resulting in phenotypes ranging from male or female infertility or both. However, little is known about the molecular role of these proteins in germ cell development. A previous study within the laboratory showed that several vertebrate Dazl family members can stimulate translation of a reporter gene in Xenopus laevis oocytes, suggesting a conserved role in mRNA specific translational control. This is consistent with studies in invertebrates. It was proposed that Dazl proteins fulfil this function through an interaction with a translation initiation factor, poly(A) binding protein, PABP. The aim of this thesis was to further refine this model of action. The work presented here investigates several fundamental questions regarding the mechanism of Dazl-mediated stimulation. First, it investigated the step of translation initiation that Dazl acts upon and explored the initiation factors that may be required. Second, it addressed in more detail the requirements for an interaction between Dazl and the poly(A) binding protein, PABP. Third, it examined the potential role of another factor, DAZ associated protein 1, DAZAP1, in Dazl-mediated stimulation. The role of multi-protein complexes containing Dazl bound to the 3’UTR that localise, repress and stimulate translation of specific mRNAs at defined times during gametogenesis are discussed.

572.8

IDENTIFICATION AND CHARACTERIZATION OF HOST FACTORS INVOLVED IN TOMBUSVIRUS REPLICATION

Jiang, Yi

01 January 2009

Positive strand RNA viruses are intracellular parasites, and their genome replication and infection involves complex virus-host interactions. Therefore, identification of host factors and dissection of their functions during virus replication could facilitate our understanding of the mechanism of virus infection. Those host factors may also provide new targets for viral disease control. Tomato bushy stunt virus (TBSV) has recently become one of the model viruses to study positive strand RNA virus replication and hostvirus interactions. To identify host factors involved in TBSV replication we used yeast as a model host. Co-expression of the replication proteins and a replicon RNA (DI RNA) via plasmids in yeast resulted in robust replication of the viral RNA. Previous work using a yeast single gene deletion library (YKO) revealed 96 yeast genes affecting virus replication. The essential yeast genes could not be deleted so we used the Yeast Tet Promoters Hughes Collection (yTHc) where the original promoter was replaced by Tetracyclin-titratable promoter. I tested the 800 essential host genes available in yTHc. In total, we found 30 new host genes whose down-regulated expression either increased or decreased the accumulation of a TBSV repRNA. The identified essential yeast genes fall into different categories on the basis of the cellular processes they are involved in, such as RNA transcription/metabolism, protein metabolism/transport etc. Detailed analysis of the effects of some of the identified yeast genes revealed that they might affect RNA replication by altering (i) the amounts of p33 and p92(pol) viral replication proteins, (ii) the activity of the tombusvirus replicase complex, and (iii) the ratio of plus- versus minus-stranded RNA replication products. Altogether, this and previous YKO screening of yeast led to the identification of 126 host genes (out of ~5,600 genes that represent ~95% of all the known and predicted yeast genes) that affected the accumulation of tombusvirus RNA. In the YKO screening, we found NSR1 (homologous to plant nucleolin) gene, whose deletion led to increased TBSV repRNA accumulation. Nucleolin is an abundant RNA binding protein, which shuttles between the nucleolus, the nucleoplasm and the cytoplasm. This protein is involved in rRNA maturation, ribosome assembly and regulation of cellular RNA metabolism.We found that over-expression of Nsr1p in yeast or nucleolin in Nicotiana benthamiana inhibited the accumulation of tombusvirus RNA by ~10-fold. Temporal regulation of Nsr1p over-expression revealed that the inhibitory effect of Nsr1p was more profound when it was expressed at early stages of viral replication. In vitro binding experiments showed that Nsr1p binds preferably to the RIII in the repRNA (which is derived from 3’ UTR of viral genome). Consistent with its RIII specific binding, over-expression of Nsr1p only reduced 40% of the accumulation of TBSVΔRIII repRNA in yeast. The purified recombinant Nsr1p inhibited the in vitro replication of the viral RNA in a yeast cell-free assay when pre-incubated with the viral RNA before the in vitro replication assay. Our data suggest that Nsr1p/nucleolin inhibits tombusvirus replication by interfering with the recruitment of the viral RNA for replication.

Plant Pathology

Isolation and functional characterization of Hrp65-binding proteins in <i>Chironomus tentans</i>

Kiesler, Eva

January 2004

<p>It is well-established that the organization of nuclear components influences gene expression processes, yet little is known about the mechanisms that contribute to the spatial co-ordination of nuclear activities. The salivary gland cells of <i>Chironomus tentans</i> provide a suitable model system for studying gene expression<i> in situ</i>, as they allow for direct visualization of the synthesis, processing and export of a specific protein-coding transcript, the Balbiani ring (BR) pre-mRNA, in a nuclear environment in which chromatin and non-chromatin structures can easily be distinguished. The RNAbinding protein Hrp65 has been identified in this model system as a protein associated with non-chromatin nucleoplasmic fibers, referred to as connecting fibers (CFs). The CFs associate with BR RNP particles in the nucleoplasm, suggesting that Hrp65 is involved in mRNA biogenesis at the post-transcriptional level. However, the function of Hrp65 is not known, nor is the function or the composition of CFs. In the work described in this thesis, we have identified by yeast two-hybrid screening and characterized different proteins that bind to Hrp65. These proteins include a novel hnRNP protein in <i>C. tentans</i> named Hrp59, various isoforms of Hrp65, the splicing- and mRNA export factor HEL/UAP56, and a RING-domain protein of unknown function. Immuno-electron microscopy experiments showed that Hrp59 and HEL are present in CFs, and in larger structures in the nucleoplasm of <i>C. tentans</i> salivary gland cells.</p><p>Hrp59 is a <i>C. tentans</i> homologue of human hnRNP M, and it associates cotranscriptionally with a subset of pre-mRNAs, including its own transcript, in a manner that does not depend quantitatively on the amount of synthesized RNA. Hrp59 accompanies the BR pre-mRNA from the gene to the nuclear envelope, and is released from the BR mRNA at the nuclear pore complex. We have identified the preferred RNA targets of Hrp59 in <i>Drosophila</i> cells, and we have shown that Hrp59 binds preferentially to exonic splicing enhancer sequences.</p><p>Hrp65 self-associates through an evolutionarily conserved domain that can also mediate heterodimerization of Hrp65 homologues. Different isoforms of Hrp65 interact with each other in all possible combinations, and Hrp65 can oligomerize into complexes of at least six molecules. The interaction between different Hrp65 isoforms is crucial for their intracellular localization, and we have discovered a mechanism by which Hrp65-2 is imported into the nucleus through binding to Hrp65-1.</p><p>Hrp65 binds to HEL/UAP56 in <i>C. tentans</i> cells. We have analyzed the distribution of the two proteins on polytene chromosomes and in the nucleoplasm of salivary gland cells, and our results suggest that Hrp65 and HEL become associated during posttranscriptional gene expression events. HEL binds to the BR pre-mRNP cotranscriptionally, and incorporation of HEL into the pre-mRNP does not depend on the location of introns along the BR pre-mRNA. HEL accompanies the BR mRNP to the nuclear pore and is released from the BR mRNP during translocation into the cytoplasm.</p>

gene expression

RNA-binding proteins

mRNA biogenesis

nuclear structure

Molecular biology

Molekylärbiologi