Estudo da via de incorporação de selenocisteínas: compreensão dos mecanismos de interações macromoleculares / Study of the selenocysteine incorporation pathway: understanding the macromolecular interaction mechanism

Scortecci, Jéssica Fernandes

04 February 2019

A existência de aminoácidos co-traducionalmente codificados pelo código genético tem estimulado estudos sobre os mecanismos de síntese, reconhecimento e incorporação nas cadeias polipeptídicas nascentes. Como exemplo, pode-se destacar a via específica de biossíntese do aminoácido selenocisteína, presente em eucariotos e procariotos, cuja incorporação ocorre juntamente ao códon de parada UGA. Em bactérias, a via de biossíntese de Sec é composta pelas proteínas Selenocisteína sintase (SelA), Fator de Elongação Específico (SelB), Selenofosfato sintetase (SelD), Seril-tRNA sintetase (SerRS) e Selenocisteína liase (CsdB). A via de síntese e incorporação de Sec depende também de dois RNAs; um tRNA específico (tRNASec) e uma sequência no mRNA (Sequência de Inserção de Selenocisteínas - SECIS), sinalizadora para correta incorporação de Sec junto ao códon UGA. Em eucariotos, essa via difere pela presença das proteínas O-fosfoseril-tRNASec Quinase (PSTK) e Selenocisteil-tRNASec sintase (SepSecS), em substituição a SelA, e pela presença de proteínas ligadoras ao elemento SECIS (SBP2). Pelo fato do selênio ter uma citotoxicidade elevada, é fundamental a compreensão do mecanismo catalítico e formação dos complexos da via na etapa de incorporação junto ao tRNASec. Em 2009, foi proposta a interação entre CsdB e SelD, porém não sendo demonstradaexperimentalmente até o momento. Dessa forma, esse estudo traz pela primeira vez, a caracterização biofísica e estrutural da interação macromolecular entre CsdB e SelD bacterianas, indicando uma elevada afinidade de interação entre elas sob diferentes condições experimentais. Estudos biofísicos mostraram que a interação aumenta a estabilidade térmica e os estudos estruturais resultaram em um modelo em baixa resolução do complexo, indicando uma assimetria para o complexo formado. Além disso, em 2013 nosso grupo anotou uma sequência putativa para uma SBP2 em N. gruberi, ameba não patogênica empregada como modelo para estudos de N. fowleri, conhecida a infectar humanos, resultando na patologia conhecida como Meningoencefalite Amebiana Primária. Deste modo, esse estudo também traz, pela primeira vez, a demonstração experimental da presença de uma SBP2 em N. gruberi Ademais, a interação desta proteína como o elemento SECIS também foi caracterizada através de diversos estudos biofísicos. Demonstrou-se que a NgSBP2 possui alto percentual de regiões de desordem e que ao interagir com o elemento SECIS apresenta enovelamento devido à interação. Dessa forma, este estudo trouxe um avanço no conhecimento das interações moleculares presentes na via de incorporação de selenocisteínas, sendo de grande relevância no entendimento dos determinantes moleculares de interação entre proteína-proteína e proteína-RNA. / The existence of co-translationally encoded amino acids by the genetic code has stimulated studies on the mechanisms of synthesis, recognition, and incorporation into new polypeptide chains. As an example, the selenocysteine (Sec) biosynthesis pathway, present in eukaryotes and prokaryotes, where the amino acid incorporation occurs at the canonical UGA stop-codon. In Bacteria, the Sec biosynthesis pathway is formed by Selenocysteine synthase (SelA), Specific Elongation Factor (SelB), Selenophosphate synthetase (SelD), Seryl-tRNA synthetase (SerRS) and Selenocysteine lyase (CsdB). The synthesis route also needs two RNAs; a specific tRNA (tRNASec) and a sequence in the mRNA (SelenoCysteine Insertion Sequence - SECIS) that encodes for the in-frame UGA Sec incorporation. In eukaryotes, the pathway is distinguished through the presence of O-phosphoseryl-tRNASec kinase (PSTK) and Selenocysteinyl-tRNASec synthase (SepSecS), replacing SelA, also the presence of SECIS binding proteins (SBP2). Once selenium presents high cell toxicity, it is crucial to fully understand the catalytic metabolism and complex formation for the tRNASec incorporation. In 2009, CsdB and SelD interaction was proposed, however, it has not been experimentally demonstrated until now. Thus, this project reports at the first time the biophysical and structural characterization of bacterial CsdB and SelD macromolecular interaction, indicating to a high-affinity interaction between these enzymes for the complex formation. Biophysical assays showed that the complex increased the thermal stability and structural studies showed a low-resolution model also indicating the macromolecule asymmetry. In addition, our research group reported in 2013 the putative SBP2 sequence in N. gruberi, the non-pathogenic amoeba used as a model for studies of N. fowleri, known as human infective, responsible for the pathology known as the Primary Amebic Meningoencephalitis. Moreover, this project also reports, at the first time, the experimental presence of N. gruberi SBP2. The SBP2.SECIS was also characterized by several biophysical methods. NgSBP2 has a high percentage of regions of disorder and access to each element SECIS presents due to interaction. Thus, this study was promoted in advance on the molecular interactions present in the incorporation of selenocysteines, being important for the understanding of the molecular determinants of the interaction between protein-protein and RNA-protein.

Interação proteína-proteína

Interação proteína-RNA

Protein-protein interaction

Protein-RNA interaction

Selenocisteína

Selenocysteine

Caracterização das interações macromoleculares das proteínas envolvidas na síntese de selenocisteínas em Escherichia coli / Characterization of the macromolecular interactions of proteins involved in the synthesis of selenocysteines in Escherichia coli

Serrão, Vitor Hugo Balasco

03 March 2017

O estudo de processos de tradução do código genético em proteínas desperta o interesse pelo seu papel central no metabolismo celular, em particular, o estudo da via de síntese de novos aminoácidos, como a selenocisteína e a pirrolisina, que resultam na expansão do código genético dos 20 aminoácidos canônicos para um total de 22 aminoácidos. A selenocisteína (Sec, U) é um aminoácido que representa a principal forma biológica do elemento selênio e sua incorporação ocorre através de um processo cotraducional em selenoproteínas como resposta ao códon UGA em fase, usualmente interpretado como códon de parada. Essa incorporação requer uma complexa maquinaria molecular distinta entre os três domínios da vida em que as selenoproteínas estão presentes: Bactéria, Arquéia e Eucária. Em Escherichia coli, a via se inicia com a aminoacilação do tRNA específico para a incorporação de selenocisteínas (SelC, tRNASec) com um resíduo de L-serina pela seril-tRNA sintetase (SerRS) formando o tRNA carregado Ser-tRNA[Ser]Sec que é entregue ao complexo homodecamérico selenocisteína sintase (SelA) responsável pela conversão Ser-Sec utilizando a forma biológica de selênio entregue pela enzima selenofosfato sintetase (SelD). Uma vez carregado com L-selenocisteína, o Sec-tRNASec é então carreado pelo fator de elongação específico para selenocisteínas (SelB) para a sua incorporação na cadeia polipeptídica nascente na posição UGA adjunta ao elemento SECIS (SElenoCysteine Insertion Sequence), uma estrutura em grampo presente no RNA mensageiro que indica o códon de inserção de selenocisteínas. Uma vez que elementos contendo selênio são tóxicos para o ambiente celular, interações entre as enzimas da via se fazem necessárias, onde as enzimas participantes em procariotos são conhecidas e caracterizadas individualmente, no entanto, suas interações macromoleculares nas diferentes etapas ainda não foram caracterizadas. Este projeto visa à caracterização macromolecular e estrutural das interações entre as enzimas SelA e SelB com os RNAs participantes tRNASec e SECIS além do ribossomo de E. coli. Para isso, amostras de SelA, SelB, tRNASec, SECIS e ribossomo foram obtidas através de diferentes metodologias. Para SelA e tRNASec foram utilizados protocolos já estabelecidos enquanto que, para SelB, fez-se necessário a otimização do protocolo previamente publicado e, consequentemente, nova caracterização biofísica através de metodologias como dicroísmo dircular (CD) e fluorescência intrínseca (IFS). Para análise das interações, medidas de espectroscopia de anisotropia de fluorescência (FAS), ultracentrifugação analítica (AUC) e calorimetria de varredura diferencial (DSC) foram utilizadas para determinação dos parâmetros de interação dos diferentes complexos estudados. Somado a isso, experimentos de cinética GTPásica foram realizados na formação dos complexos e, além disso, foram gerados modelos estruturais utilizando diferentes metodologias como espalhamento de raios-X a baixo ângulo (SAXS) além de estudos por microscopia eletrônica de transmissão (TEM). Os estudos propostos irão auxiliar no entendimento do mecanismo de incorporação deste aminoácido em bactérias bem como nos demais domínios da vida além de elucidar o mecanismo sequencial de eventos, provendo conhecimento e desenvolvendo metodologias para sistemas complexos de interação proteína-proteína e proteína-RNA. / The study of genetic code processes in proteins is a central role in cell metabolism, in particular the study of the synthesis pathway of new amino acids, such as selenocysteine and pyrrolisine, which resulted in the expansion of the genetic code of the 20 canonical amino acids for 22 amino acids. Selenocysteine (Sec, U) is an amino acid that represents a major biological form of selenium element and its incorporation through a co-translational process in selenoproteins in response to the in-phase UGA-codon, usually interpreted as stop-codon. This incorporation requires a complex molecular machinery distinct between the three domains of life in which, as selenoprotein has present: Bacteria, Archaea and Eukaria. In Escherichia coli, an initiation pathway with an aminoacylation of the tRNA specific for the incorporation of selenocysteines (SelC, tRNASec) with an L-serine residue by seril-tRNA synthetase (SerRS) resulting in the charged tRNA Ser-tRNA[Ser] Sec that is delivered to the homodecameric complex selenocysteine synthase (SelA), responsible for Ser-Sec conversion using the biological form of selenium delivered by the enzyme selenophosphate synthetase (SelD). Once loaded with L-selenocysteine, Sec-tRNASec is then carried by the selenocysteine-specific elongation factor (SelB) for incorporation into the nascent polypeptide chain at the UGA position attached to the SECIS (SElenoCysteine Insertion Sequence) element, staple structure that indicates the insertion codon of selenocysteines. Since elements containing selenium are toxic to the cell, interactions between how pathway enzymes are made, where the enzymes participating in concepts are known and characterized individually, however, their macromolecular interactions in the different steps have not yet been characterized. This project aims at the macromolecular and structural characterization of the interactions between SelA and SelB enzymes with the RNAS tRNASec and SECIS participants in addition to the E. coli ribosome. For this, as samples of SelA, SelB, tRNASec, SECIS and ribosome were obtained through different methodologies. For SelA and tRNASec, protocols were used to determine parameters for SelB, it was necessary to optimize a previously published protocol and, consequently, a new biophysical characterization through methodologies such as circular dichroism (CD) and intrinsic fluorescence spectroscopy (IFS). To analyze the interactions, measurements of fluorescence anisotropy spectroscopy (FAS), analytical ultracentrifugation (AUC) and differential scanning calorimetry (DSC) were used to determine the interaction parameters of different complexes studied. In addition, GTPases activity experiments were carried out in the formation of the complexesand, in addition, we have generated models that characterize different methodologies such as small angles X-ray scattering (SAXS) and transmission electron microscopy (TEM). The proposed studies will aid in understanding the mechanism of incorporation of this amino acid into bacteria as well as the other domains of life besides elucidating the sequential mechanism of events, providing knowledge and development of methodologies for complex protein-protein and RNA-protein interaction systems.

Interação proteína-proteína

Interação proteína-RNA

Protein-protein interaction

Protein-RNA interaction

Selenocisteína

Selenocysteine

Caracterização das interações macromoleculares das proteínas envolvidas na síntese de selenocisteínas em Escherichia coli / Characterization of the macromolecular interactions of proteins involved in the synthesis of selenocysteines in Escherichia coli

Vitor Hugo Balasco Serrão

03 March 2017

O estudo de processos de tradução do código genético em proteínas desperta o interesse pelo seu papel central no metabolismo celular, em particular, o estudo da via de síntese de novos aminoácidos, como a selenocisteína e a pirrolisina, que resultam na expansão do código genético dos 20 aminoácidos canônicos para um total de 22 aminoácidos. A selenocisteína (Sec, U) é um aminoácido que representa a principal forma biológica do elemento selênio e sua incorporação ocorre através de um processo cotraducional em selenoproteínas como resposta ao códon UGA em fase, usualmente interpretado como códon de parada. Essa incorporação requer uma complexa maquinaria molecular distinta entre os três domínios da vida em que as selenoproteínas estão presentes: Bactéria, Arquéia e Eucária. Em Escherichia coli, a via se inicia com a aminoacilação do tRNA específico para a incorporação de selenocisteínas (SelC, tRNASec) com um resíduo de L-serina pela seril-tRNA sintetase (SerRS) formando o tRNA carregado Ser-tRNA[Ser]Sec que é entregue ao complexo homodecamérico selenocisteína sintase (SelA) responsável pela conversão Ser-Sec utilizando a forma biológica de selênio entregue pela enzima selenofosfato sintetase (SelD). Uma vez carregado com L-selenocisteína, o Sec-tRNASec é então carreado pelo fator de elongação específico para selenocisteínas (SelB) para a sua incorporação na cadeia polipeptídica nascente na posição UGA adjunta ao elemento SECIS (SElenoCysteine Insertion Sequence), uma estrutura em grampo presente no RNA mensageiro que indica o códon de inserção de selenocisteínas. Uma vez que elementos contendo selênio são tóxicos para o ambiente celular, interações entre as enzimas da via se fazem necessárias, onde as enzimas participantes em procariotos são conhecidas e caracterizadas individualmente, no entanto, suas interações macromoleculares nas diferentes etapas ainda não foram caracterizadas. Este projeto visa à caracterização macromolecular e estrutural das interações entre as enzimas SelA e SelB com os RNAs participantes tRNASec e SECIS além do ribossomo de E. coli. Para isso, amostras de SelA, SelB, tRNASec, SECIS e ribossomo foram obtidas através de diferentes metodologias. Para SelA e tRNASec foram utilizados protocolos já estabelecidos enquanto que, para SelB, fez-se necessário a otimização do protocolo previamente publicado e, consequentemente, nova caracterização biofísica através de metodologias como dicroísmo dircular (CD) e fluorescência intrínseca (IFS). Para análise das interações, medidas de espectroscopia de anisotropia de fluorescência (FAS), ultracentrifugação analítica (AUC) e calorimetria de varredura diferencial (DSC) foram utilizadas para determinação dos parâmetros de interação dos diferentes complexos estudados. Somado a isso, experimentos de cinética GTPásica foram realizados na formação dos complexos e, além disso, foram gerados modelos estruturais utilizando diferentes metodologias como espalhamento de raios-X a baixo ângulo (SAXS) além de estudos por microscopia eletrônica de transmissão (TEM). Os estudos propostos irão auxiliar no entendimento do mecanismo de incorporação deste aminoácido em bactérias bem como nos demais domínios da vida além de elucidar o mecanismo sequencial de eventos, provendo conhecimento e desenvolvendo metodologias para sistemas complexos de interação proteína-proteína e proteína-RNA. / The study of genetic code processes in proteins is a central role in cell metabolism, in particular the study of the synthesis pathway of new amino acids, such as selenocysteine and pyrrolisine, which resulted in the expansion of the genetic code of the 20 canonical amino acids for 22 amino acids. Selenocysteine (Sec, U) is an amino acid that represents a major biological form of selenium element and its incorporation through a co-translational process in selenoproteins in response to the in-phase UGA-codon, usually interpreted as stop-codon. This incorporation requires a complex molecular machinery distinct between the three domains of life in which, as selenoprotein has present: Bacteria, Archaea and Eukaria. In Escherichia coli, an initiation pathway with an aminoacylation of the tRNA specific for the incorporation of selenocysteines (SelC, tRNASec) with an L-serine residue by seril-tRNA synthetase (SerRS) resulting in the charged tRNA Ser-tRNA[Ser] Sec that is delivered to the homodecameric complex selenocysteine synthase (SelA), responsible for Ser-Sec conversion using the biological form of selenium delivered by the enzyme selenophosphate synthetase (SelD). Once loaded with L-selenocysteine, Sec-tRNASec is then carried by the selenocysteine-specific elongation factor (SelB) for incorporation into the nascent polypeptide chain at the UGA position attached to the SECIS (SElenoCysteine Insertion Sequence) element, staple structure that indicates the insertion codon of selenocysteines. Since elements containing selenium are toxic to the cell, interactions between how pathway enzymes are made, where the enzymes participating in concepts are known and characterized individually, however, their macromolecular interactions in the different steps have not yet been characterized. This project aims at the macromolecular and structural characterization of the interactions between SelA and SelB enzymes with the RNAS tRNASec and SECIS participants in addition to the E. coli ribosome. For this, as samples of SelA, SelB, tRNASec, SECIS and ribosome were obtained through different methodologies. For SelA and tRNASec, protocols were used to determine parameters for SelB, it was necessary to optimize a previously published protocol and, consequently, a new biophysical characterization through methodologies such as circular dichroism (CD) and intrinsic fluorescence spectroscopy (IFS). To analyze the interactions, measurements of fluorescence anisotropy spectroscopy (FAS), analytical ultracentrifugation (AUC) and differential scanning calorimetry (DSC) were used to determine the interaction parameters of different complexes studied. In addition, GTPases activity experiments were carried out in the formation of the complexesand, in addition, we have generated models that characterize different methodologies such as small angles X-ray scattering (SAXS) and transmission electron microscopy (TEM). The proposed studies will aid in understanding the mechanism of incorporation of this amino acid into bacteria as well as the other domains of life besides elucidating the sequential mechanism of events, providing knowledge and development of methodologies for complex protein-protein and RNA-protein interaction systems.

Interação proteína-proteína

Interação proteína-RNA

Selenocisteína

Protein-protein interaction

Protein-RNA interaction

Selenocysteine

Structural basis for translational regulation by RNA-binding protein Musashi-1 / RNA結合タンパク質Musashi-1による翻訳制御の構造基盤

Iwaoka, Ryo

25 September 2017

京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第20729号 / エネ博第357号 / 新制||エネ||70(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)教授 片平 正人, 教授 森井 孝, 教授 木下 正弘 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DGAM

RNA-binding protein

Musashi-1

Protein-RNA interaction

Structure determination

Model building

501

Caracterização das proteinas humanas Mov34 e PACT e analise da sua interação com o RNA do virus da dengue / Characterization of the human Mov34 and PACT proteins and analyses of their interaction with dengue virus RNA

Alves, Beatriz Santos Capela

21 August 2008

Orientador: Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-11T18:49:26Z (GMT). No. of bitstreams: 1 Alves_BeatrizSantosCapela_D.pdf: 5512305 bytes, checksum: 707ea6299bc24ddc6fb459520d79aeee (MD5) Previous issue date: 2008 / Resumo: O combate à dengue atualmente está limitado praticamente aos esforços de eliminação do mosquito transmissor, o Aedes aegypti, porém esta estratégia não tem se mostrado eficiente. O desenvolvimento de novos instrumentos de combate à dengue requer, portanto, maior conhecimento sobre a biologia do vírus com relação à sua interação com seus hospedeiros. O genoma do vírus é constituído por um RNA simples-fita de polaridade positiva e possui duas regiões não traduzidas (5¿ e 3¿ UTR). A região 5¿UTR viral possui organização similar à dos mRNAs eucarióticos, diferentemente da região 3¿UTR que é longa e não possui cauda de poli(A). Em vez disso, na região 3¿UTR encontram-se estruturas conservadas entre os diferentes Flavivirus, dentre elas a estrutura 3¿ stem-loop (3¿SL) que é indispensável para a replicação do RNA viral. O objetivo do nosso estudo foi identificar novas proteínas humanas capazes de interagir com a estrutura 3¿SL do RNA do vírus da dengue. Dados da literatura descrevem que a proteína Mov34 de camundongo interage com 3¿SL do vírus da encefalite japonesa. Devido à alta similaridade entre as proteínas ortólogas humana e de camundongo, bem como das respectivas estruturas 3¿SL dos vírus da dengue e da encefalite japonesa, foi testada a interação entre a Mov34 humana com o 3¿SL do vírus da dengue. Porém, em nenhuma das condições testadas foi possível obter evidência de interação da Mov34 humana com 3¿SL dos vírus da dengue e da encefalite japonesa. Para a identificação de novas proteínas que são capazes de interagir com a estrutura 3¿SL do RNA do vírus da dengue foi utilizado o ensaio de triplo-híbrido de levedura. A proteína humana PACT, conhecida como proteína celular ativadora de PKR, foi isolada neste ensaio utilizando 3¿SL como isca. PKR é uma quinase ativada por PACT ou RNA dupla-fita. A ativação de PKR leva a um estado antiviral adquirido pela fosforilação do fator de iniciação da tradução eIF2a e conseqüente inibição da tradução. Além disso, PKR está envolvida em outras vias de transdução de sinal e na resposta celular à proteínas desenoveladas. A ação antiviral de PACT é evidenciada pela ação de proteínas dos vírus influenza A e herpes simplex tipo 1 que inibem a ativação de PKR por PACT e por RNA dupla-fita. A interação direta de PACT com 3¿SL do RNA do vírus da dengue foi confirmada por ensaio de UVcrosslinking PACT possui três domínios de interação com RNA dupla-fita, sendo que os dois domínios N-terminais são responsáveis pela sua interação com o 3¿SL. Foi identificada uma região específica do 3¿SL, o stem-loop superior, onde PACT interage com maior afinidade. Além disso, foi mostrado que PACT endógena de células HEK293 é capaz de interagir com o 3¿SL biotinilado. Para caracterizar a função desta interação durante a infecção viral, foi desenvolvida uma linhagem celular com inibição da expressão de PACT através da técnica de RNA de interferência. Com esta linhagem poderemos analisar a importância da interação entre PACT e o RNA do vírus da dengue quanto à ativação e/ou inibição de PKR durante a infecção viral / Abstract: The combat to the dengue virus is basically limited to the efforts in eliminating the transmitter mosquito, the Aedes aegypti. But this strategy is not very efficient. The development of new instruments of combat to dengue virus requires improved knowledge about the virus biology and its relation to hosts. The dengue virus genome is a single-stranded RNA of positive polarity flanked by a 5¿ untranslated region (UTR) of ~100 bases and a highly structured 3¿ UTR of ~450 bases. As many other viruses, dengue encodes the enzymes required for its genome replication, but relies completely on the host translational machinery to synthesize its proteins. The essential difference between host cellular mRNAs and dengue virus genome RNA involves the 3¿UTR, which instead of a polyadenylate tail contains highly conserved structural elements, including the 3' stem-loop (3¿SL), located at the 3' terminus of the 3'UTR of many flaviviruses that is essential for their replication. The aim of this study is to identify new human proteins capable of interacting with dengue virus RNA 3¿SL structure. Literature data describe that the murine Mov34 protein interacts with Japanese encephalitis virus 3¿SL. Giving the high similarity between the human and murine ortholog proteins, as well as the conservation of the Flavivivirus RNA 3¿SL structure, we tested the interaction between the human Mov34 and the dengue virus 3¿SL. However, no interaction was detected under the conditions used in this work. In addition, the yeast three-hybrid system was used to screen for novel proteins that interact with the dengue virus 3¿SL. Human PACT, known as the cellular protein activator of PKR, was identified as a putative 3¿SL-interacting protein. PKR is an interferon-inducible, PACT or double-stranded RNA activated protein kinase. Activated PKR phosphorylates the translation initiation factor eIF2a, inhibiting translation of cellular and viral RNAs, leading to a cellular antiviral state. PACT and doublestranded RNA activation of PKR is inhibited by influenza A and herpes simplex type 1 virus proteins during viral infection, indicating that PACT plays a role in the cellular antiviral state. Direct interaction between PACT and 3¿SL was confirmed by UV-crosslinking assays. PACT contains three doublestranded RNA interaction motifs, but only the two N-terminal motifs are responsible for 3¿SL interaction. A 3¿SL specific region, the top stem-loop, was identified to interact with PACT with higher affinity. Furthermore, HEK293 cells endogenous PACT interacts with biotin-labeled 3¿SL. To further characterize PACT-3¿SL interaction during dengue virus infection, a cell line with low expression of PACT was developed using the RNA interference technique. This cell line will be used to determine the propagation rate of dengue virus which is expected to reveal the importance of PACT either for the cell antiviral state or for dengue virus proliferation / Doutorado / Genetica Animal e Evolução / Doutor em Genetica e Biologia Molecular

Proteina mov34 humana

Proteina PACT humana

Vírus da dengue

Interação proteína-RNA

Human Mov34 protein

Human PACT protein

Dengue viruses

Protein-RNA interaction

3' untranslated regions

Caractérisation des enzymes de formation de la coiffe du virus du Nil Occidental et du métapneumovirus humain / Characterization of capping enzyme of West Nile Virus and human metapneumovirus

Collet, Axelle

03 December 2015

Ma thèse a porté sur l’étude des activités enzymatiques impliquées dans la formation de la coiffe de deux virus à ARN: le virus du Nil Occidental (WNV) et le métapneumovirus humain (hMPV). Ces virus codent pour des enzymes assurant l’ajout de la coiffe de type-1 (m7GpppN2’Om) à l’extrémité 5’ de leur ARNm.Le domaine N-terminal de la protéine NS5 (NS5MTase) du WNV porte les activités N7- et 2’O-méthyltransférases (N7- et 2’O-MTases) et il a été proposé que NS5MTase puisse également porter l’activité guanylyltransférase (GTase). J’ai identifié in vitro des résidus clés impliqués dans l’interaction entre NS5MTase et des ARN substrats de chaque activité MTase. Nos résultats démontrent que le site de fixation de la coiffe est nécessaire lors de la 2’O-méthylation et ne l’est pas pour la N7-méthylation. En parallèle, j’ai recherché des résidus catalytiques de la GTase par la méthode de génétique inverse. Des résultats préliminaires indiquent que la mutation K29A induit un défaut de réplication. Ce résidu pourrait donc être impliqué dans l’activité GTase de NS5MTase.Concernant hMPV, j’ai effectué une analyse fonctionnelle du domaine CR-VI+ de la protéine L. J’ai démontré que CR-VI+ possède les activités N7- et 2’O-MTases et j’ai identifié les résidus impliqués dans le recrutement de l’ARNm. L’ordre de méthylation est non canonique avec la 2’O-méthylation qui précède la N7-méthylation. Enfin, j’ai également démontré que CR-VI+ possède une activité d’hydrolyse du GTP.Ce travail démontre que ces MTases possèdent 2 voire 3 des activités enzymatiques nécessaires à la formation de la coiffe, et représentent donc une cible de choix pour le développement d’inhibiteurs. / My PhD project is focus on the study of the enzymatic activities involved in the RNA capping pathway of two RNA viruses: the West Nile Virus (WNV) and the human metapneumovirus (hMPV). These viruses encode for enzymes allowing the addition of a cap-1 structure (m7GpppN2’Om) to their mRNA 5’ ends. The NS5 N-terminal domain (NS5MTase) of WNV harbours the N7- and 2’O-methyltransferase activities (N7- and 2’O-MTase); and it has been proposed that NS5MTase also bears a guanylyltransferase activity (GTase). I have identified residues involved in the NS5MTase interaction sites with their RNAs substrate. My assays demonstrate the importance of the cap-binding site for the 2’O-methylation but not for the N7-methylation. In parallel, I have tried to identify putative catalytic residues of the GTase activity by reverse genetics. Preliminary results suggest that NS5MTase K29 could be a catalytic residue.Concerning hMPV, I performed a functional analysis of CR-VI+ domain of the protein L. I demonstrated that the CR-VI+ domain harbours the N7- and 2’O-MTase activities and identified the residues involved in the mRNA recruitment. I showed that the methylation order is not canonical with the 2’O-methylation preceding the N7-methylation. Finally, I showed that the domain harbours an additional GTP hydrolysis activity, representing the first step of RNA cap formation for Mononegavirales.This work demonstrates that this MTase domains harbour 2 or 3 of the enzymatic activities required for viral RNA cap synthesis and represent attractive targets for the development of antivirals.

Virus du Nil Occidental

Métapneumovirus humain

Coiffe des ARNm

Méthyltransférase

Guanylyltransférase

Interactions protéine-ARN

West Nile Virus

Human metapneumovirus

MRNA cap

Methyltransferase

Guanylyltransferase

Protein-RNA interaction

570

Caractérisation de l’interaction entre la protéine Lin28 et le précurseur du microARN let-7g

Desjardins, Alexandre

08 1900

La régulation de l’expression des gènes est ce qui permet à nos cellules de s’adapter à leur environnement, de combattre les infections ou, plus généralement, de produire la quantité exacte de protéine nécessaire pour répondre à un besoin spécifique. Parmi les joueurs les plus importants dans cette régulation de l’expression des gènes on retrouve les microARN (miARN). Ces petits ARN de 22 nucléotides sont présents chez la majorité des espèces multicellulaires et sont responsables du contrôle direct de plus de 30% des gènes exprimant des protéines chez les vertébrés. La famille de miARN lethal-7 (let-7) est composée de miARN parmi les plus connus et ayant des fonctions cruciales pour la cellule. La régulation du niveau des miARN let-7 est essentielle au bon développement cellulaire. La biogenèse de ces miARN, du transcrit primaire jusqu’à leur forme mature, est régulée principalement par Lin28, une protéine pluripotente très conservée. Cette protéine est composée d’un domaine cold shock (CSD) et de deux domaines de liaison au zinc. C’est grâce à ces domaines de liaison à l’ARN que Lin28 peut lier et inhiber la maturation des miARN let-7. L’objectif de cette thèse est de caractériser l’interaction entre Lin28 et le microARN précurseur let-7g afin de mieux comprendre le rôle de cette protéine dans l’inhibition de la biogenèse du miARN. À l’aide de techniques biochimiques et biophysiques, nous avons d’abord défini les principaux déterminants de l’interaction entre Lin28 et la boucle terminale du miARN précurseur let-7g (TL-let-7g). Nous avons conclu que le domaine C-terminal de Lin28, composé d’un motif riche en lysines et arginines ainsi que de deux motifs de liaison au zinc, permet à la protéine de lier spécifiquement et avec haute affinité un renflement riche en guanine conservé chez les précurseurs de la famille let-7. Aussi, parce que la séquence et la spécificité de liaison à l’ARN de ce domaine C-terminal sont semblables à celles de la protéine NCp7 du VIH, nous avons défini ce dernier comme le domaine NCp7-like de Lin28. Par la suite, nous avons caractérisé la multimérisation de trois protéines Lin28 sur la boucle terminale de pre-let-7g. Ceci a permis de réconcilier d’apparentes contradictions retrouvées dans la littérature actuelle concernant les sites de liaison de Lin28 lors de sa liaison aux miARN précurseurs. Nous avons identifié trois sites de liaison à haute affinité sur TL-let-7g qui sont liés dans un ordre précis par trois protéines Lin28. Lors de la formation du complexe multimérique, le CSD permet une déstabilisation de l’ARN, ce qui rend accessible plusieurs sites de liaison. Le domaine NCp7-like permet plutôt un assemblage ordonné de la protéine et facilite la liaison initiale de cette dernière. Ces nouveaux résultats rendent possible la mise au point d’un nouveau modèle de l’interaction entre Lin28 et le miARN précurseur let-7g. En conclusion, les études réalisées dans cette thèse apportent une meilleure compréhension des mécanismes moléculaires impliqués dans la régulation post-transcriptionnelle d’une importante famille de miARN et permettront de guider les futures études dans le domaine de recherche en pleine effervescence qu’est celui de la biogenèse des miARN. / The regulation of gene expression is what allows our cells to adapt to their environment, to fight infections or, more generally, to express the appropriate level of proteins to meet a specific need. The microRNAs (miRNAs) are among the most important players in the regulation of gene expression. These small RNAs of 22 nucleotides are present in most multicellular species and are responsible for the direct control of more than 30% of protein-expressing genes in vertebrates. The miRNA lethal-7 (let-7) family consist of some of the most studied miRNAs and plays crucial roles in the cell. The appropriate regulation of the let-7 miRNAs level is essential for proper cellular development. The biogenesis of these miRNAs, from the primary transcript to their mature form is mainly regulated by Lin28, a highly-conserved pluripotent protein. This protein is composed of a cold shock domain (CSD) and two zinc-binding domains. These RNA-binding domains allow Lin28 to bind and inhibit the maturation of the let-7 miRNA. The objective of this thesis is to characterize the interaction between the Lin28 protein and the let-7g miRNA precursor to better understand the role of this protein in the inhibition of miARN biogenesis. Using biochemical and biophysical techniques, we first identified the main determinants of the interaction between Lin28 and the terminal loop of the precursor miRNA let-7g (TL-let-7g). We concluded that the C-terminal domain of Lin28, composed of a lysine-rich and arginine-rich motif in addition to two zinc-binding motifs, is sufficient to bind with high affinity a conserved guanine-rich bulge located on the TL-let-7g. In addition, because the sequence and RNA-binding specificity of this C-terminal domain are similar to those of the HIV protein NCp7, we defined this region as the NCp7-like domain of Lin28. Subsequently, we characterized the multimerization of three Lin28 proteins on the terminal loop of pre-let-7g. This study helped to reconcile apparent contradictions found in the current literature regarding the Lin28-binding sites on miRNA precursors. We identified three high-affinity binding sites on TL-let-7g that are bound in a stepwise manner by the three Lin28 proteins. As part of the formation of the multimeric complex, both RNA-binding domains of Lin28 play an important role. The CSD destabilizes the RNA and this exposes several binding sites, whereas the NCp7-like domain allows an orderly protein assembly and facilitates the initial binding of the protein. These results lead us to propose a new model for the interaction between Lin28 and pre-let-7g. In conclusion, these studies provide a better understanding of the molecular mechanisms involved in the post-transcriptional regulation of an important family of miRNAs and will help guide future projects in the expanding research area of miRNA biogenesis.

Lin28

let-7

microARN

régulation post-transcriptionnelle

interaction protéine-ARN

gels natifs

microRNA

post-transcriptional regulation

protein-RNA interaction

macromolecular complex formation

native gels

Compréhension des rôles des complexes Nob1/Pno1 et RPS14/Cinap dans la maturation cytoplasmique de la petite sous-unité ribosomique (pré-40S) chez les eucaryotes / Understanding Nob1/Pno1 and RPS14/Cinap complexes roles in the cytoplasmic maturation of the eukaryotic small ribosomal subunit (pre-40S)

Raoelijaona, Raivoniaina

14 November 2019

Les ribosomes sont des complexes nucléoproétiques responsables de la traduction. Chez les eucaryotes, la biogenèse du ribosome est un processus complexe très régulé qui fait intervenir un nombre important de facteurs d’assemblages (~200). La construction d’un ribosome est initiée dans le nucléole puis continue dans le nucléoplasme et se termine dans le cytoplasme. La maturation cytoplasmique de la petite sous-unité ribosomale implique la dissociation séquentielle des facteurs d’assemblage tardifs et la maturation finale de l’ARNr 18S. Ce processus est catalysé par l’endonucléase Nob1 qui assure la coupure de l’extrémité 3’ du précurseur de l’ARNr 18S (pré-18S) aboutissant à sa forme mature. Ce mécanisme est coordonné par la protéine Pno1 qui est le partenaire de Nob1. Des informations détaillées sur l’architecture des particules pré-ribosomiques nous ont permis de mieux comprendre les différents intermédiaires de la biogenèse. Cependant, certains aspects fonctionnels comme la conformation adoptée par Nob1 pour assurer la coupure du site D du pre-18S reste encore flou. L’objectif de mon travail a été de mieux comprendre les aspects très tardifs de la maturation cytoplasmique du ribosome. Pour ce faire, nous avons redéfini l’organisation modulaire de l’endonucléase Nob1 chez les eucaryotes pour ensuite étudier son mode d’interaction avec son partenaire Pno1. Des tests fonctionnels in vitro ont été effectués pour étudier le rôle de Pno1 dans la régulation de la coupure par Nob1.Nos résultats nous ont permis de montrer que le domaine catalytique de Nob1 adopte une conformation atypique. En effet le domaine PIN est composé de deux fragments (res 1-104 and 230-255) séparé par une boucle interne qui est importante pour la reconnaissance avec son partenaire Pno1. Nos études nous ont également montré que Pno1 inhibe l’activité de Nob1 probablement en reconnaissant directement l’ARNr substrat, masquant ainsi le site de coupure de l’endonucléase. Ces résultats sont complémentaires et cohérents avec les données structurales de cryo-EM de la particule pré-40S humaine récemment publiées. En effet, Nob1 est dans une conformation incapable de couper le pré-ARNr puisque son domaine catalytique se retrouve à une distance d’environ 30Å de son ARN substrat. Ce phénomène implique donc des changements de conformations ou encore la nécessité de protéine accessoire pour déplacer certains facteurs. La protéine Cinap est impliqué dans la maturation de l’ARNr 18S. Nos études d’interaction avec les protéines localisées au niveau de la plateforme (à savoir RPS14, RPS26, le complexe Nob1/Pno1) ont permis de montrer que Cinap pouvait former un complexe tripartite avec l’endonucléase Nob1 et son partenaire Pno1. De plus, Cinap est capable de reconnaitre RPS26 dans un complexe RPS14-dépendant. Il est important de noter que RPS26 est un composant de la petite sous-unité qui remplace Pno1 dans le ribosome mature. De ce fait le recrutement de RPS26 au sein du pré-ribosome nécessite la dissociation de Pno1 et cet échange serait assurée par Cinap. Sur la base des travaux effectués, nous pouvons proposer un modèle de maturation où la formation du complexe Cinap/Pno1 induirait un changement de conformation permettant à Nob1 de reconnaitre son substrat et donc de catalyser la coupure du site D qui aboutit à la maturation de l’ARNr 18S et donc à la production de la sous-unité 40S mature. / Ribosomes are translational machineries universally responsible of protein synthesis. In eukaryote, ribosome assembly is a complex and highly regulated process that requires coordinated action of more than 200 biogenesis factors. Ribosome assembly is initiated in the nucleolus, continues in the nucleoplasm and terminates in the cytoplasm. The cytoplasmic maturation events of the small ribosomal subunit are associated with sequential release of the late assembly factors and concomitant maturation of the pre-rRNA. During final maturation of the small subunit, the pre-18S rRNA is cleaved off by the endonuclease Nob1, which activity is coordinated by its binding partner Pno1. Detailed information on pre-ribosomal particle architectures have been provided by structural snapshots of maturation events. However, key functional aspects such as the architecture required for pre-rRNA cleavage have remained elusive. In order to better understand these late steps of cytoplasmic pre-40S maturation, we first redefine the domain organization of Nob1, then study its binding mode with Pno1 using different tools such as sequence analysis, structure prediction and biochemical experiments and, we then performed functional assay to elucidate the role played by Pno1 during the pre-18S rRNA maturation.Our results have shown that eukaryotic Nob1 adopts an atypical PIN domain conformation: two fragments (res 1-104 and 230-255) separated by an internal loop, which is essential for Pno1 recognition. We also found out that Pno1 inhibits Nob1 activity likely by masking the cleavage site. Our findings further support the recently published cryo-EM structure of the pre-40S, where Nob1 displays an inactive conformation. Moreover, 18S rRNA 3’-end cleavage has to happen and this implies structural rearrangement or requirement of some accessory proteins such as Cinap, an atypical kinase involved in pre-18S processing. Studying the interplay between proteins localized in the pre-40S platform (RPS14, RPS26, Nob1/Pno1 complex) has shown that Cinap is able to form a trimeric complex with Nob1 and its binding partner Pno1. Furthermore, Cinap can recognize RPS26 in a RPS14-dependent manner, which had already been studied with its yeast counterpart. It is important to note that RPS26 is the ribosomal protein replacing Pno1 in the mature ribosome. Our finding clearly suggests a mechanism where RPS26 recruitment to the ribosome requires Pno1 dissociation. This exchange would be carried out by Cinap. Therefore, we can suggest a simplified model as follow: upon binding with Pno1, the newly formed complex (Cinap/Pno1) will trigger a conformational change, which will allow the endonuclease Nob1 to reach its substrate (D-site) and perform its cleavage resulting in mature 18 rRNA generation.

Biogenèse du ribosome

Maturation de l'ARN 18S

Complexe Nob1/Pno1

Clivage de l'extrémité 3' du pré-18S

Interaction protéique

Ribosome biogenesis

18S RNA maturation

Nob1/Pno1 complex

Pre-18S rRNA 3' end cleavage

Protein - protein/RNA interaction

Exploring Protein-Nucleic Acid Interactions Using Graph And Network Approaches

Sathyapriya, R

03 1900

The flow of genetic information from genes to proteins is mediated through proteins which interact with the nucleic acids at several stages to successfully transmit the information from the nucleus to the cell cytoplasm. Unlike in the case of protein-protein interactions, the principles behind protein-nucleic acid interactions are still not very (Pabo and Nekludova, 2000) and efforts are still underway to arrive at the basic principles behind the specific recognition of nucleic acids by proteins (Prabakaran et al., 2006). This is mainly due to the innate complexity involved in recognition of nucleotides by proteins, where, even within a given family of DNA binding proteins, different modes of binding and recognition strategies are employed to suit their function (Luscomb et al., 2000). Such difficulties have also not made possible, a thorough classification of DNA/RNA binding proteins based on the mode of interaction as well as the specificity of recognition of the nucleotides. The availability of a large number of structures of protein-nucleic acids complexes (albeit lesser than the number of protein structures present in the PDB) in the past few decades has provided the knowledge-base for understanding the details behind their molecular mechanisms (Berman et al., 1992). Previously, studies have been carried out to characterize these interactions by analyzing specific non-covalent interactions such as hydrogen bonds, van der Walls, and hydrophobic interactions between a given amino acid and the nucleic acid (DNA, RNA) in a pair-wise manner, or through the analysis of interface areas of the protein-nucleic acid complexes (Nadassy et al., 1998; Jones et al., 1999). Though the studies have deciphered the common pairing preferences of a particular amino acid with a given nucleotide of DNA or RNA, there is little room for understanding these specificities in the context of spatial interactions at a global level from the protein-nucleic acid complexes. The representation of the amino acids and the nucleotides as components of graphs, and trying to explore the nature of the interactions at a level higher than exploring the individual pair-wise interactions, could provide greater details about the nature of these interactions and their specificity. This thesis reports the study of protein-nucleic interactions using graph and network based approaches. The evaluation of the parameters for characterizing protein-nucleic acid graphs have been carried out for the first time and these parameters have been successfully employed to capture biologically important non-covalent interactions as clusters of interacting amino acids and nucleotides from different protein-DNA and protein-RNA complexes. Graph and network based approaches are well established in the field of protein structure analysis for analyzing protein structure, stability and function (Kannan and Vishveshwara, 1999; Brinda and Vishveshwara, 2005). However, the use of graph and network principles for analyzing structures of protein-nucleic acid complexes is so far not accomplished and is being reported the first time in this thesis. The matter embodied in the thesis is presented as ten chapters. Chapter 1 lays the foundation for the study, surveying relevant literature from the field. Chapter 2 describes in detail the methods used in constructing graphs and networks from protein-nucleic acid complexes. Initially, only protein structure graphs and networks are constructed from proteins known to interact with specific DNA or RNA, and inferences with regard to nucleic acid binding and recognition were indirectly obtained . Subsequently, parameters were evaluated for representing both the interacting amino acids and the nucleotides as components of graphs and a direct evaluation of protein-DNA and Protein-RNA interactions as graphs has been carried out. Chapter 3 and 4 discuss the graph and network approaches applied to proteins from a dataset of DNA binding proteins complexed with DNA. In chapter 3, the protein structure graphs were constructed on the basis of the non-covalent interactions existing between the side chains of amino acids. Clusters of interacting side chains from the graphs were obtained using the graph spectral method. The clusters from the protein-DNA interface were analyzed in detail for the interaction geometry and biological importance (Sathyapriya and Vishveshwara, 2004). Chapter 4 also uses the same dataset of DNA binding proteins, but a network-based approach is presented. From the analysis of the protein structure networks from these DNA binding proteins, interesting observations relating the presence of highly connected nodes(or hubs) of the network to functionally important amino acids in the structure, emerged. Also, the comparison between the hubs identified from the protein-protein and the protein-DNA interfaces in terms of their amino acid composition and their connectivity are also presented (Sathyapriya and Vishveshwara, 2006) Chapter 5 and 6 deal with the graph and network applications to a specific system of protein-RNA complex (aminoacyl-tRNA synthetases) to gain insights into their interface biology based on amino acid connectivity. Chapter 5 deals with a dataset of aminoacyl-tRNA synthetase (aaRS) complexes obtained with various ligands like ATP, tRNA and L-amino acids. A graph based identification of side chain clusters from these ligand-bound aaRS structures has highlighted important features of ligand-binding at the catalytic sites of the two structurally different classes of aaRS (Class I and Class II). Side chain clusters from other regions of aaRS such as the anticodon binding region and the ligand-activation sites are discussed. A network approach is used in a specific system of aaRS(E.coli Glutaminyl-tRNA synthetase (GlnRS) complexed with its ligands, to specifically understand the effects of different ligand binding., in chapter 6. The structure networks of E.coli GlnRS in the ligand-free and different ligand-bound states are constructed. The ligand-free and the ligand-bound complexes are compared by analyzing their network properties and the presence of hubs to understand the effect of ligand-binding. These properties have elegantly captured the effects of ligand-binding to the GlnRS structure and have also provided an alternate method for comparing three dimensional structures of proteins in different ligand-bound states (Sathyapriya and Vishveshwara, 2007). In contrast to protein structure graphs (PSG), both the interacting amino acids and nucleotides (DNA/RNA) form the components of the protein-nucleic acid graphs (PNG) from protein-nucleic acid complexes. These graphs are constructed based on the non-covalent interactions existing between the side chains of the amino acids and nucleotides. After representing the interacting nucleotides and amino acids as graphs, clusters of the interacting components are identified. These clusters are the strongly interacting amino acids and nucleotides from the protein-nucleic acid complexes. These clusters can be generated at different strengths of interaction between the amino acid side chain and the nucleotide (measured in terms of its atomic connectivity) and can be used for detecting clusters of non-specific as well as specific interactions of amino acids and nucleotides. Though the methodology of graph construction and cluster identification are given in chapter 2, the details of the parameters evaluated for constructing PNG are given in chapter 7. Unlike in the previous chapters, the succeeding chapters deal exclusively with results that are obtained from the analyses of PNG. Two examples of obtaining clusters from a PNG are given, one each for a protein-DNA and a protein-RNA complex. In the first example, a nucleosome core particle is subjected to the graph based analysis and different clusters of amino acids with different regions of the DNA chain such as phosphate, deoxyribose sugar and the base are identified. Another example of aminoacyl-tRNA synthetase complexed with its cognate tRNA is used to illustrate the method with a protein-RNA complex. Further, the method of constructing and analyzing protein-nucleic acid graphs has been applied to the macromolecular machinery of the pre-translocation complex of the T. thermophilus 70S ribosome. Chapter 8 deals exclusively with the results identified from the analysis of this magnificent macromolecular ensemble. The availability of the method that can handle interactions between both amino acids and the nucleotides of the protein-nucleic acid complexes has given us the basis fro evaluating these interactions in a level higher than that of analyzing pair-wise interactions. A study on the evaluation of short hydrogen bonds(SHB) in proteins, which does not fall under the realm of the main objective of the thesis, is discussed in the Chapter 9. The short hydrogen bonds, defined by the geometrical distance and angle parameters, are identified from a non-redundant dataset of proteins. The insights into their occurrence, amino acid composition and secondary structural preferences are discussed. The SHB are present in distinct regions of protein three-dimensional structures, such that they mediate specific geometrical constraints that are necessary for stability of the structure (Sathyapriya and Vishveshwara, 2005). The significant conclusions of various studies carried out are summarized in the last chapter (Chapter 10). In conclusion, this thesis reports the analyses performed with protein-nucleic acid complexes using graph and network based methods. The parameters necessary for representing both amino acids and the nucleotides as components of a graph, are evaluated for the first time and can be used subsequently for other analyses. More importantly, the use of graph-based methods has resulted in considering the interaction between the amino acids and the nucleotides at a global level with respect to their topology of the protein-nucleic acid complexes. Such studies performed on a wide variety of protein-nucleic acid complexes could provide more insights into the details of protein-nucleic acid recognition mechanisms. The results of these studies can be used for rational design of experimental mutations that ascertain the structure-function relationships in proteins and protein-nucleic acid complexes.

Protein-Nucleic Acid Interactions

Protein-RNA Interactions

Protein Structure Graphs

Protein Nucleotide Graphs (PNG)

Protein-DNA Complexes

Protein-RNA Complexes

Aminoacyl-tRNA Synthetase

Glutaminyl-tRNA Synthetase (GlnRS)

Proteins - Short Hydrogen Bonds

Protein Structure Networks

Protein-RNA Interaction

Structure Graphs

Protein-RNA Graphs

70S Ribosome

Biochemical Genetics

Engineering post-transcriptional regulation of gene expression with RNA-binding proteins

Dolcemascolo, Roswitha

23 January 2024

[ES] La biología sintética tiene como objetivo diseñar y construir nuevos sistemas biológicos con funciones deseadas. Los circuitos basados en el control transcripcional han tenido preponderancia en este campo tras el trabajo pionero del toggle switch y del repressilator. Sin embargo, para avanzar en la creación de tecnologías transformadoras que utilicen circuitos genéticos sintéticos, es esencial una combinación de mecanismos de control confiables en todo el flujo de la información genética. Esta combinación es necesaria para alcanzar el nivel de integrabilidad y complejidad funcional observado en la naturaleza. En tal sentido, recientemente han ganado atención los circuitos basados en regulación postranscripcional. En particular, se ha aprovechado la gran programabilidad de ARN para crear circuitos reguladores para la biodetección de señales ambientales o para controlar la vía metabólica en la bioproducción. En esta tesis, por el contrario, proponemos explotar las proteínas de unión a ARN para diseñar circuitos sintéticos que operen a nivel de traducción en la bacteria Escherichia coli. Esta tesis pretende estudiar como surge y se propaga el ruido cuando la expresión genética está regulada por un factor de traducción, y la ampliación de la caja de herramientas de la biología sintética con una nueva caracterización de proteínas de unión a ARN adecuadas. Por un lado, hemos diseñado un circuito de control postrancripcional utilizando la proteína de cápside del fago MS2. Mediante una meticulosa monitorización a nivel unicelular tanto del regulador como del gen regulado, hemos cuantificado el comportamiento dinámico del sistema, así como su estocasticidad. Si bien los esfuerzos anteriores se centraron en comprender la propagación del ruido en las regulaciones transcripcionales, el comportamiento estocástico de los genes regulados a nivel de la traducción sigue siendo en gran medida desconocido. Nuestros datos han revelado que un factor de traducción de proteínas ha permitido una fuerte represión a nivel unicelular, ha amortiguado la propagación del ruido de un gen a otro y ha conducido a una sensibilidad no lineal a las perturbaciones globales en la traducción. Estos descubrimientos han mejorado significativamente nuestra comprensión de la expresión genética estocástica y han proporcionado principios de diseño fundamentales para aplicaciones de biología sintéticas. Por otro lado, aprovechamos el motivo de reconocimiento de ARN (RRM), el dominio proteico de unión a ARN mas prevalente en la naturaleza, a pesar de su predominio en los filos eucariotas, para diseñar un sistema de control postranscripcional ortogonal en Escherichia coli. Aprovechando la proteína de unión a ARN de mamífero Musashi-1, que contiene dos RRM canónicos, desarrollamos un circuito sofisticado. Musashi-1 ha funcionado como represor de la traducción alostérico a través de su interacción especifica con la región codificante N-terminal del ARN mensajero, mostrando capacidad de respuesta a los ácidos grasos. La caracterización integral tanto a nivel poblacional como unicelular ha destacado un cambio significativo en la expresión del reportero. Se obtuvieron conocimientos moleculares a través de la cinética de unión in vitro y evaluaciones de funcionalidad in vivo de una serie de mutantes de ARN. Este trabajo ha mostrado la adaptabilidad de la regulación basada en RRM a organismos mas simples, introduciendo una nueva capa regulatoria para el control de la traducción en procariotas y, en ultima instancia, ampliando los horizontes de la manipulación genética. / [CA] La biologia sintètica té per objectiu dissenyar i construir nous sistemes biològics amb funcions desitjades. Els circuits basats en el control transcripcional han tingut preponderancia en aquest camp després del treball pioner del toggle switch i del repressilator. Tot i això, per avançar en la creació de tecnologies transformadres que utilitzin circuits genètics sintètics, és esencial una combinació de mecanismes de control fiables en tot el flux de la información genètica. Aquesta combinació és necessària per assolir el nivel d'integrabilitat i complexitat funcional observat a la natura. En aquest sentit, recentement han guanyat atenció els circuits basats en regulació posttranscripcional. En particular, s'ha aprofitat la gran programabilitat d'ARN per crear circuits reguladors per a la biodetecció de senyals ambientals o per controlar la via metabólica a la bioproducció. En aquesta tesi, per contra, proposem exlotar les proteïnes d'unió a ARN per dissenyar circuits sintètics que operin a nivel de traducció al bacteri Escherichia coli. Aquesta tesi pretén estudiar com sorgeix i es propaga el soroll quan l'expressió genètica està regulada per un factor de traducció, il'ampliació de la caixa d'eines de la biología sintètica amb una nova caracteriació de proteïnes d'unió a ARN adequades. D'una banda, hem dissenyat un circuit de control postranscripcional utilitzant la proteína de càpsid del fag MS2. Mitjançant una meticulosa monitorització a nivel inucel·lular tant del regulador com del gen regulat, hem quantificat el comportament dinàmic del sistema, així com la seva estocasticitat. Tot i que els esforços anteriors es van centrar a comprendre la propagació del soroll en les regulacions transcripcionals, el comportament estocàstic dels gens regulats a nivell de la traducció continua sent en gran mesura desonegut. Les nostres dades han revelat que un factor de traducció de proteïnes ha permès una forta repressió a nivell unicel·lular, ha esmorteït la propagació del soroll d'un gen a un altre i ha conduït a una sensibilitat no lineal a les pertorbacions globals a la traducció. Aquest descobriments han millorat significativament la nostra comprensió de l'expressió genètica estocástica i han proporcionat principis de sisseny fonamentals per a aplicacions de biología sintètiques. D'altra banda, aprofitem el motiu de reconeixement d'ARN (RRM), el domini proteic d'unió a ARN més prevalent a la natura, malgrat el seu predomini als talls eucariotes, per dissenyar un sistema de control posttranscripcional ortogonal a Escherichia coli. Aprofitant la proteína d'unió a ARN de mamífers Musashi-1, que conté dos RRM canònics, hem desenvolupat un circuit sofisticat. Musashi-1 va funcionar com un repressor de la traducció al·lostèric a través de la seva interacció específica amb la regió codificant N-terminal de l'ARN missatger, mostrant capacitat de resposta als àcids grassos. La caracterització integral tant a nivel poblacional com unicèl·lular va destacar un canvi significatiu a l'expressió de l'informador. S'obtingueren coneixements moleculars a través de la cinètica d'unió in vitro i avaluacions de funcionalitat in vivo d'una sèrie de mutants d'ARN. Aquest treball va mostrar l'adaptabilitat de la regulació basada en RRM a organismos més simples, introduint una nova capa regulatòria per al control de la traducció en procariotes i, en darrer terme, ampliant els horitzons de la manipulació genètica. / [EN] Synthetic biology seeks to design and construct new biological systems with desired functions. Circuits based on transcriptional control have been preponderant in the field following the pioneering work of the toggle switch and repressilator. However, to advance the creation of transformative technologies using synthetic genetic circuits, a blend of dependable control mechanisms throughout the genetic information flow is essential. This combination is necessary to attain the level of integrability and functional complexity observed in nature. In this regard, circuits based on post-transcriptional regulation have recently gained attention. In particular, the great programmability of RNA has been exploited to create regulatory circuits for biosensing of environmental signals or for controlling metabolic pathway in bioproduction. In this thesis, in contrast, we propose to exploit RNA-binding proteins to engineer synthetic circuits that operate at the level of translation in the bacterium Escherichia coli. This thesis intends to study how noise emerges and propagates when gene expression is regulated by a translation factor, and the expansion of the synthetic biology toolbox with new characterization of suitable RNA-binding proteins. On the one hand, we engineered a post-transcriptional control circuit using the phage MS2 coat protein. Through meticulous single-cell level monitoring of both the regulator and the regulated gene, we quantified the dynamic behavior of the system, as well as their stochasticity. While previous efforts focused on understanding noise propagation in transcriptional regulations, the stochastic behavior of genes regulated at the translation level remain largely unknown. Our data revealed that a protein translation factor enabled strong repression at the single-cell level, buffered noise propagation from gene to gene, and led to a nonlinear sensitivity to global perturbations in translation. These findings significantly enhanced our understanding of stochastic gene expression and provided foundational design principles for synthetic biology applications. On the other hand, we harnessed the RNA recognition motif (RRM), the most prevalent RNA-binding domain in nature, despite its predominance in eukaryotic phyla, to engineer an orthogonal post-transcriptional control system in Escherichia coli. Leveraging the mammalian RNA-binding protein Musashi-1, which contains two canonical RRMs, we developed a sophisticated circuit. Musashi-1 functioned as an allosteric translation repressor through its specific interactions with the N-terminal coding region of messenger RNA, exhibiting responsiveness to fatty acids. Comprehensive characterization at both population and single-cell levels highlighted a significant fold change in reporter expression. Molecular insights were gleaned through in vitro binding kinetics and in vivo functionality assessments of a series of RNA mutants. This work showcased the adaptability of RRM-based regulation to simpler organisms, introducing a novel regulatory layer for translation control in prokaryotes, ultimately expanding the horizons of genetic manipulation. / Dolcemascolo, R. (2023). Engineering post-transcriptional regulation of gene expression with RNA-binding proteins [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/202194

Systems biology

Genetic circuits

Mathematical modeling

Protein-RNA interaction

Post-transcriptional regulation

Binding kinetics

Dynamic systems

RNA recognition motif

Synthetic biology

Biología de sistemas

Biología sintética

Sistemas dinámicos

Cinética de unión

Regulación postranscripcional

Interacción proteína-ARN

Modelización matemática

Circuitos genéticos

Motivo de reconocimiento de ARN