Identification And Characterization Of A Virus Inducible Non Coding RNA (VINC)

Sreenivasa Murthy, U M

02 1900

Non-protein coding eukaryotic genome sequences often referred to as junk DNA are estimated to encode several non-coding RNAs (ncRNAs) which may account for nearly 98% of all genomic output in humans. The output of such a wide spread transcription in eukaryotes consists of intronic, antisense and small RNAs. In addition to the classical ncRNAs such as rRNA, tRNA and small nucleolar RNAs, the eukaryotic genome encodes two distinct categories of ncRNAs, referred to as small ncRNAs and long mRNA–like ncRNAs (mlncRNAs). The long ncRNAs, which are transcribed by RNA Polymerase II, spliced and polyadenylated, are implicated in a number of regulatory processes such as imprinting, X-chromosome inactivation, DNA demethylation, transcription, RNA interference, chromatin structure dynamics and antisense mediated regulation. Expression of noncoding RNAs is altered during stress conditions and a large number of such transcripts have been identified of late. This study has identified a novel ncRNA whose expression is upregulated during viral infection of mouse brain. While we have named this RNA as VINC or virus inducible ncRNA, others have named it as NEAT1 (Hutchinson et al., 2007) and Men (Sunwoo et al., 2008). VINC/NEAT1/Men is associated with a distinct nuclear domain called paraspeckles Using a cell line as well as an animal model system we have investigated VINC in great detail and based on these studies we report that VINC is a nuclear ncRNA that localizes to paraspeckles and it interacts with the paraspeckle protein, P54nrb in both cell line model system as well as in animal tissues by a combination of in vitro and in vivo methods. We have also mapped the domains within VINC that are involved in P54nrb interactions. Till date, the only other RNA known to localise to paraspeckles is CTN-RNA. While CTN-RNA is a protein coding RNA, VINC does not code for a protein and thus VINC is the first ncRNA to be localized to paraspeckles. Further, the mechanism of nuclear retention of these two paraspeckle RNAs appears to be distinct. In case of CTN-RNA, it has been clearly shown that it is A-I edited and such hyperedited RNAs are retained by the p54/nrb mediated complex in nucleus (Zhang and Carmichael, 2001). However the mechanism by which VINC is retained in nucleus is not clear. There is apparently no A-I editing in VINC and hence VINC retention in the nucleus by binding to nuclear proteins such as p54/nrb might involve a different mechanism. It is well established of late that nuclear matrix retains RNAs and that there is a population of poly (A) RNA that is retained in nucleus (Huang et al.,1994 ; Carter et al.,1991). However the significance of such retention is not clear but it is believed that it might be important for some constitutive functions in nucleus (Nickerson et al., 1989). More investigations are needed to understand the exact functions of nuclear RNAs such as VINC in supporting the nuclear architecture. P54nrb is a multi functional nuclear protein that mediates most of its functions in association with PSF (Shav-Tal and Zipori, 2002). Phosphorylation status of P54nrb is a key determinant for its localisation to various nuclear regions. P54nrb is a multiphosphorylated protein during mitosis and its phosphorylation is mediated by PIN-1 at its C-terminus (Proteau et al., 2005). Tyrosine phosphorylation of P54nrb is essential for it to be retained in nuclear matrix (Otto et al., 2001). The N-terminal phosphorylation is speculated but not much has been investigated. The protein has two distinct RNA recognition motifs (RRMs) in its N-terminus that are responsible for its RNA binding activity. The significance of the p54/nrb-PSF heterodimer cannot be undermined as they have been shown to be important during HIV replication. The dimer is recruited by viral machinery and P54nrb has been shown to be exported to cytosol for binding to replicative complexes (Zolotukhin et al., 2003). During adenoviral replication in nucleus many SR proteins are recruited to viral replication foci and rearrangement of speckle components happen. It has been shown with respect to speckles that nuclear domains are highly dynamic and exchange of proteins depends upon the transcriptional status of cell (Lamond and Spector, 2003). Flaviviral replication complexes are hosted in nucleus and ~20% of this complex docks in nucleus and serves as an alternate site for viral replication. The presence of viral replicative complexes alters the nuclear organisation and hence modulation of gene expression is expected (Uchil et al., 2006). The up regulation of nuclear ncRNA such as VINC is definitively one of those events associated with viral replication and definitively one needs to study the various changes carefully to understand the role of VINC in virus life cycle and/or viral pathogenesis. VINC interaction with the multi-functional nuclear protein P54nrb raises interesting aspects related to function of P54nrb in JEV infection. Knockdown of P54nrb in human myeloid cell line results in abnormal size of paraspeckles and impairs chondrogenesis (Hata et al., 2008). PSF-P54nrb complex can divert many of HIV gag RNA complexes to paraspeckles thus trying to restrict viral replication. However the exact relationship between paraspeckles and its constituent proteins is not clear. The presence of ncRNA adds another new dimension to paraspeckles. It is unclear whether the ncRNA VINC is essential for paraspeckle structure but a recent study indicates that Men (VINC/NEATI) RNA may be essential for paraspeckle formation (Sunwoo et al., 2008). The exact function VINC in neuronal as well as non-neuronal cell nuclei remains elusive and more investigations are need to understand these aspects.

Virus Inducible Non Coding RNA

RNA (Ribonucleic Acid)

RNA-Protein Interactions

Non-Coding RNAs

Gene Expression

Nuclear RNA-binding Protein

VINC

Non-coding RNAs (ncRNAs)

Biochemical Genetics

Non-Coding RNA-Based Biosensors for Early Detection of Liver Cancer

Falahi, Sedigheh, Rafiee-Pour, Hossain-Ali, Zarejousheghani, Mashaalah, Rahimi, Parvaneh, Joseph, Yvonne

12 July 2024

Primary liver cancer is an aggressive, lethal malignancy that ranks as the fourth leading cause of cancer-related death worldwide. Its 5-year mortality rate is estimated to be more than 95%. This significant low survival rate is due to poor diagnosis, which can be referred to as the lack of sufficient and early-stage detection methods. Many liver cancer-associated non-coding RNAs (ncRNAs) have been extensively examined to serve as promising biomarkers for precise diagnostics, prognostics, and the evaluation of the therapeutic progress. For the simple, rapid, and selective ncRNA detection, various nanomaterial-enhanced biosensors have been developed based on electrochemical, optical, and electromechanical detection methods. This review presents ncRNAs as the potential biomarkers for the early-stage diagnosis of liver cancer. Moreover, a comprehensive overview of recent developments in nanobiosensors for liver cancer-related ncRNA detection is provided.

info:eu-repo/classification/ddc/620

ddc:620

Nanostrukturiertes Material

Leberkrebs

Biosensor

Non-coding RNA

O transcritoma antisense primário de Halobacterium salinarum NRC-1 / The antisense primary transcriptome of Halobacterium salinarum NRC-1

João Paulo Pereira de Almeida

04 September 2018

Em procariotos, RNAs antisense (asRNAs) constituem a classe de RNAs não codificantes (ncRNAs) mais numerosa detectada por métodos de avaliação de transcritoma em larga escala. Apesar da grande abundância, pouco se sabe sobre mecanismos regulatórios e aspectos da conservação evolutiva dessas moléculas, principalmente em arquéias, onde o mecanismo de degradação de RNAs dupla fita (dsRNAs) é um fenômeno pouco conhecido. No presente estudo, utilizando dados de dRNA-seq, identificamos 1626 inícios de transcrição primários antisense (aTSSs) no genoma de Halobacterium salinarum NRC-1, importante organismo modelo para estudos de regulação gênica no domínio Archaea. Integrando dados de expressão gênica obtidos a partir de 18 bibliotecas de RNA-seq paired-end, anotamos 846 asRNAs a partir dos aTSSs mapeados. Encontramos asRNAs em ~21% dos genes anotados, alguns desses relacionados a importantes características desse organismo como: codificadores de proteínas que constituem vesículas de gás e da proteína bacteriorodopsina, além de vários genes relacionados a maquinaria de tradução e transposases. Além desses, encontramos asRNAs em genes pertencentes a sistemas de toxinas-antitoxinas do tipo II e utilizando dados públicos de dRNA-seq, evidenciamos que esse é um fenômeno que ocorre em bactérias e arquéias. A interação de um ncRNA com seu RNA alvo pode ser dependente de proteínas, em arquéias, a proteína LSm é uma chaperona de RNA homóloga a Hfq de bactérias, implicada no controle pós-transcricional. Utilizamos dados de RIP-seq de RNAs imunoprecipitados com LSm e identificamos 91 asRNAs interagindo com essa proteína, para 81 desses, o mRNA do gene sense também foi encontrado interagindo. Buscando por aTSSs presentes nas mesmas regiões de genes ortólogos, identificamos 160 aTSSs que dão origem a asRNAs em H. salinarum possivelmente conservados em Haloferax volcanii. A expressão dos asRNAs anotados foi avaliada ao longo de uma curva de crescimento e em uma linhagem knockout de um gene que codifica uma RNase R, possível degradadora de dsRNAs em arquéias. Encontramos um total de 144 asRNAs diferencialmente expressos ao longo da curva de crescimento, para 56 desses o gene sense também está diferencialmente expresso, caracterizando possíveis mecanismos de regulação em cis por esses RNAs. Na linhagem knockout, encontramos cinco asRNAs diferencialmente expressos e apenas para um desses o gene sense também está diferencialmente expresso, resultado que não nos permitiu inferir um possível papel de degradação de dsRNAs da RNAse R em H. salinarum NRC-1. Nesse trabalho apresentamos um mapeamento completo do transcritoma antisense primário de H. salinarum NRC-1 com resultados que consistem em um importante passo na direção da compreensão do envolvimento da transcrição antisense na regulação gênica pós-transcricional desse organismo modelo do terceiro domínio da vida. / Antisense RNAs (asRNAs) constitute the most numerous class of non-coding RNAs (ncRNAs) detected by transcriptome highthroughput methods in prokaryotes. Despite this abundance, little is known about regulatory mechanisms and evolutionary aspects of these molecules, mainly in archaea, where the mechanism of double-strand RNA (dsRNA) degradation remains poorly understood. In this study, using dRNA-seq data, we identified 1626 antisense transcription start sites (aTSSs) in the genome of Halobacterium salinarum NRC-1, an important model organism for gene expression regulation studies in Archaea. By integrating gene expression data from 18 RNA-seq paired-end libraries, we were able to annotate 846 asRNAs from mapped aTSSs. We found asRNAs in ~21% of annotated genes including genes related to important characteristics of this organism, such as: gas vesicle proteins, bacteriorhodopsin, translation machinery and transposases. We also found asRNAs in type II toxin-antitoxin systems and using public dRNA-seq data, we show evidences that this phenomenon might be conserved in archaea and bacteria. The interaction of a ncRNA with its target may depend on intermediary proteins action. In archaea, the LSm protein is a RNA chaperone homologous to bacterial Hfq, involved in post-transcriptional regulation. We used RIP-seq data from RNAs immunoprecipitated with LSm and identified 91 asRNAs interacting with this protein, for 81 of these the mRNA of the sense gene is also interacting. We searched for aTSSs present in the same region of orthologous genes in the Haloferax volcanii. We found 160 aTSSs that originated asRNAs in H. salinarum NRC-1 that might be conserved in this two archaea. The expression of annotated asRNAs was analyzed over a growth curve and in a knockout strain for RNase R gene. We found 144 asRNA differentially expressed over the growth curve, for 56 of these the sense gene was also differentially expressed, characterizing possible cis regulators asRNAs. In the knockout strain we found five differentially expressed asRNAs and only one asRNA/gene pair, this result does not allow us to infer a dsRNA degradation in vivo activity for this RNase in H. salinarum NRC- 1. This work contributes to the discovery of the antisense transcriptome in H. salinarum NRC- 1 a relevant step to uncover the post-transcriptional gene regulatory network in this archaeon.

Archaea

Differential RNA-seq (dRNA-seq)

Halobacterium salinarum

Lsm

RNAs antisense (asRNAs)

RNAs dupla fita (dsRNAs)

RNAs não codificantes (ncRNAs)

RNAse R

Sistemas toxinas-antitoxinas (TAs)

Antisense RNAs (asRNAs)

Archaea

Differential RNA-seq (dRNA-seq)

Double-strand RNAs (dsRNAs)

Halobacterium salinarum

LSm

Non-coding RNAs (ncRNAs)

RNAse R

Toxins-antitoxins systems (TAs)

Transcription start sites (TSSs)

O transcritoma antisense primário de Halobacterium salinarum NRC-1 / The antisense primary transcriptome of Halobacterium salinarum NRC-1

Almeida, João Paulo Pereira de

04 September 2018

Em procariotos, RNAs antisense (asRNAs) constituem a classe de RNAs não codificantes (ncRNAs) mais numerosa detectada por métodos de avaliação de transcritoma em larga escala. Apesar da grande abundância, pouco se sabe sobre mecanismos regulatórios e aspectos da conservação evolutiva dessas moléculas, principalmente em arquéias, onde o mecanismo de degradação de RNAs dupla fita (dsRNAs) é um fenômeno pouco conhecido. No presente estudo, utilizando dados de dRNA-seq, identificamos 1626 inícios de transcrição primários antisense (aTSSs) no genoma de Halobacterium salinarum NRC-1, importante organismo modelo para estudos de regulação gênica no domínio Archaea. Integrando dados de expressão gênica obtidos a partir de 18 bibliotecas de RNA-seq paired-end, anotamos 846 asRNAs a partir dos aTSSs mapeados. Encontramos asRNAs em ~21% dos genes anotados, alguns desses relacionados a importantes características desse organismo como: codificadores de proteínas que constituem vesículas de gás e da proteína bacteriorodopsina, além de vários genes relacionados a maquinaria de tradução e transposases. Além desses, encontramos asRNAs em genes pertencentes a sistemas de toxinas-antitoxinas do tipo II e utilizando dados públicos de dRNA-seq, evidenciamos que esse é um fenômeno que ocorre em bactérias e arquéias. A interação de um ncRNA com seu RNA alvo pode ser dependente de proteínas, em arquéias, a proteína LSm é uma chaperona de RNA homóloga a Hfq de bactérias, implicada no controle pós-transcricional. Utilizamos dados de RIP-seq de RNAs imunoprecipitados com LSm e identificamos 91 asRNAs interagindo com essa proteína, para 81 desses, o mRNA do gene sense também foi encontrado interagindo. Buscando por aTSSs presentes nas mesmas regiões de genes ortólogos, identificamos 160 aTSSs que dão origem a asRNAs em H. salinarum possivelmente conservados em Haloferax volcanii. A expressão dos asRNAs anotados foi avaliada ao longo de uma curva de crescimento e em uma linhagem knockout de um gene que codifica uma RNase R, possível degradadora de dsRNAs em arquéias. Encontramos um total de 144 asRNAs diferencialmente expressos ao longo da curva de crescimento, para 56 desses o gene sense também está diferencialmente expresso, caracterizando possíveis mecanismos de regulação em cis por esses RNAs. Na linhagem knockout, encontramos cinco asRNAs diferencialmente expressos e apenas para um desses o gene sense também está diferencialmente expresso, resultado que não nos permitiu inferir um possível papel de degradação de dsRNAs da RNAse R em H. salinarum NRC-1. Nesse trabalho apresentamos um mapeamento completo do transcritoma antisense primário de H. salinarum NRC-1 com resultados que consistem em um importante passo na direção da compreensão do envolvimento da transcrição antisense na regulação gênica pós-transcricional desse organismo modelo do terceiro domínio da vida. / Antisense RNAs (asRNAs) constitute the most numerous class of non-coding RNAs (ncRNAs) detected by transcriptome highthroughput methods in prokaryotes. Despite this abundance, little is known about regulatory mechanisms and evolutionary aspects of these molecules, mainly in archaea, where the mechanism of double-strand RNA (dsRNA) degradation remains poorly understood. In this study, using dRNA-seq data, we identified 1626 antisense transcription start sites (aTSSs) in the genome of Halobacterium salinarum NRC-1, an important model organism for gene expression regulation studies in Archaea. By integrating gene expression data from 18 RNA-seq paired-end libraries, we were able to annotate 846 asRNAs from mapped aTSSs. We found asRNAs in ~21% of annotated genes including genes related to important characteristics of this organism, such as: gas vesicle proteins, bacteriorhodopsin, translation machinery and transposases. We also found asRNAs in type II toxin-antitoxin systems and using public dRNA-seq data, we show evidences that this phenomenon might be conserved in archaea and bacteria. The interaction of a ncRNA with its target may depend on intermediary proteins action. In archaea, the LSm protein is a RNA chaperone homologous to bacterial Hfq, involved in post-transcriptional regulation. We used RIP-seq data from RNAs immunoprecipitated with LSm and identified 91 asRNAs interacting with this protein, for 81 of these the mRNA of the sense gene is also interacting. We searched for aTSSs present in the same region of orthologous genes in the Haloferax volcanii. We found 160 aTSSs that originated asRNAs in H. salinarum NRC-1 that might be conserved in this two archaea. The expression of annotated asRNAs was analyzed over a growth curve and in a knockout strain for RNase R gene. We found 144 asRNA differentially expressed over the growth curve, for 56 of these the sense gene was also differentially expressed, characterizing possible cis regulators asRNAs. In the knockout strain we found five differentially expressed asRNAs and only one asRNA/gene pair, this result does not allow us to infer a dsRNA degradation in vivo activity for this RNase in H. salinarum NRC- 1. This work contributes to the discovery of the antisense transcriptome in H. salinarum NRC- 1 a relevant step to uncover the post-transcriptional gene regulatory network in this archaeon.

Antisense RNAs (asRNAs)

Archaea

Archaea

Differential RNA-seq (dRNA-seq)

Differential RNA-seq (dRNA-seq)

Double-strand RNAs (dsRNAs)

Halobacterium salinarum

Halobacterium salinarum

LSm

Lsm

Non-coding RNAs (ncRNAs)

RNAs antisense (asRNAs)

RNAs dupla fita (dsRNAs)

RNAs não codificantes (ncRNAs)

RNAse R

RNAse R

Sistemas toxinas-antitoxinas (TAs)

Toxins-antitoxins systems (TAs)

Transcription start sites (TSSs)