Caracterização de um Novo Gene da Família F-box Expresso no Pistilo de Nicotiana tabacum L. / Characterization of a New F-box Family Gene Expressed in the Nicotiana tabacum L. Pistil

Abbad, Samantha Vieira

13 August 2012

O estudo da reprodução sexual de plantas e uma área de crescente interesse devido a importância de sementes e frutos em nossa dieta diária, ambos resultantes do desenvolvimento de partes do pistilo, apos fertilização. O objetivo deste trabalho foi caracterizar um novo gene F-box expresso no pistilo de N. tabacum. Proteínas F-box atuam na interação proteína-proteína, geralmente direcionando proteínas alvo para degradação pela via ubiquitina-proteassomo. Foram identificados cinco genes de função desconhecida que codificam putativas proteínas F-box, em duas bibliotecas de cDNAs de estigmas/estiletes de N. tabacum (DEPAOLI, 2006; QUIAPIM et al., 2009) previamente construídas em nosso laboratório. A expressão de cada um destes genes foi analisada nos diferentes órgãos de N. tabacum, por qRT-PCR. O clone 085H05 da biblioteca TOBEST (QUIAPIM et al., 2009) apresentou expressão preferencial nos órgãos florais. Este clone foi selecionado para uma caracterização funcional mais detalhada. O padrão de expressão deste gene foi avaliado no estigma/estilete durante os 12 estádios do desenvolvimento floral de N. tabacum (KOLTUNOW et al., 1990). O resultado revelou que sua expressão e regulada durante o desenvolvimento, atingindo o maior nível de expressão na antese (estádio 12). Isto sugere que este gene esteja envolvido no desenvolvimento do estigma/estilete. A sequência codificadora do gene correspondente a 085H05 foi determinada e, apos amplificação e clonagem, este gene foi denominado S/S_F-box (Stigma/Style_F-box). Para compreender a função da proteína de S/S_F-box, plantas transgênicas de superexpressao e de silenciamento (por RNAi) deste gene foram geradas. As plantas de RNAi apresentaram o estilete e o ovário reduzidos quando comparados ao controle SR1. Em concordância, as plantas de superexpressao produziram flores com o estilete mais alongado do que o controle, alem do estigma e do ovário de maior tamanho. Altas concentrações de exudato foram observadas na superfície do estigma destas plantas, a partir do estádio 7 tardio. No controle SR1, concentrações equivalentes apenas são observadas nos estádios finais do desenvolvimento. Os fenótipos observados nas plantas transgênicas sugerem que a proteína codificada por S/S_F-box esteja envolvida com o desenvolvimento do pistilo e com o controle do tamanho deste órgão. Adicionalmente, as plantas de RNAi apresentaram o fenótipo de perda da dominância apical. Os níveis de expressão do gene S/S_F-box foram avaliados em plantas que tiveram aumento na produção de auxina no estigma/estilete (plantas STIG1prom::iaaM), revelando que este gene não e regulado, a nível transcricional, por este hormônio. Experimentos de localização subcelular, realizados por expressão transitória da sequência de S/S_F-box fusionada a sequência dos genes repórteres GFP e YFP (S/S_F-box::GFP; S/S_F-box::YFP), indicaram que a proteína S/S_F-box esta localizada no citoplasma e no núcleo celular. Adicionalmente, foi realizado o screening de uma biblioteca de cDNAs de estigma/estilete, construída no sistema de duplo-hibrido, para investigar proteínas candidatas a interagirem com a proteína de S/S_F-box. Os resultados indicaram interação da proteína S/S_F-box com SKP1, confirmando a participação de S/S_F-box no complexo SCF, que promove a degradação de proteínas alvo pela via ubiquitina-proteassomo. Duas proteínas candidatas a alvo foram identificadas: os fatores de transcrição VOZ1 e SIP1, ambos envolvidos com a proliferação celular. Em suma, e possível propor que a proteína codificada por S/S_F-box tenha função relacionada a proliferação celular e ao desenvolvimento dos órgãos vegetais, incluindo o pistilo. / The study of sexual reproduction in plants is an area of increasing interest due to the importance of seeds and fruits in our daily diet, both resulting from the development of parts of the pistil, after fertilization. The aim of this study was to characterize a new F-box gene expressed in the N. tabacum pistil. F-box proteins act in protein-protein interactions, generally directing target proteins to degradation via ubiquitin-proteasome. Five genes of unknown function coding for putative F-box proteins were identified at two cDNAs libraries from N. tabacum stigmas/styles (DEPAOLI, 2006; QUIAPIM et al., 2009), previously constructed in our laboratory. The expression of each of these genes was analyzed in the different N. tabacum organs, by qRT-PCR. The 085H05 clone from the TOBEST library (QUIAPIM et al., 2009) showed preferential expression in floral organs. This clone was select for a more detailed functional characterization. The expression pattern of this gene was evaluated in the stigma/style during the 12 N. tabacum flower developmental stages (KOLTUNOW et al., 1990). The result revealed that its expression is regulated during development, reaching the highest expression level at anthesis (stage 12). It suggests that this gene is involved in the stigma/style development. The coding sequence of the gene corresponding to 085H05 was determined and, after amplification and cloning, the gene was named S/S_F-box (Stigma/Style_F-box). To understand the S/S_F-box protein function, transgenic plants either overexpressing or silencing (by RNAi) the S/S_F-box gene were generated. The RNAi plants showed reduced style and ovary when compared to the control SR1. In accordance, the overexpressing plants produced flowers with a style more elongated than the control, besides an ovary and a stigma of larger size. High concentrations of exudate were observed on the stigma surface of these plants, since the later stage 7. In the control SR1, equivalent concentrations are only observed at the later stages of development. The phenotypes observed in the transgenic plants suggest that the protein encoded by S/S_F-box is involved with pistil development and with the control of pistil size. Additionally, the RNAi plants showed the phenotype of loss of apical dominance. The expression levels of the S/S_F-box gene were evaluated in plants with increased auxin production in the stigma/style (plants STIG1prom::iaaM), showing that this gene is not transcriptionally regulated by this hormone. Subcellular localization experiments, carried out by transient expression of the S/S_F-box sequence fused to the reporter genes GFP and YFP V (S/S_F-box::GFP; S/S_F-box::YFP), showed that the S/S_F-box protein is localized in the cytoplasm and in the nucleus. Additionally, the screening of a stigma/style cDNA library constructed on the yeast two hybrid system was performed, to investigate candidate proteins for S/S_F-box protein interaction. The results indicated interaction between S/S_Fbox and the SKP1 protein, confirming the involvement of the S/S_F-box protein in the SCF complex, which promotes degradation of target proteins via ubiquitin-proteasome. Two candidates for target proteins were identified: the transcription factors VOZ1 and SIP1, both involved in cell proliferation. In summary, it is possible to propose that the protein encoded by S/S_F-box has functions related to cell proliferation and organ development, including the pistil.

Cell proliferation

Complexo SCF

Duplo-híbrido

Estigma/estilete

F-box

F-box

Kelch subfamily

Localização subcelular

Plantas transgênicas

Proliferação celular

SCF complex

Stigma/style

Subcellular localization

Subfamília Kelch

Transgenic plants

Two-hybrid

Ubiquitinação

Ubiquitination

Structural and biochemical analysis of cullin-based ubiquitin ligases reveal regulatory mechanisms of ubiquitination machinery /

Goldenberg, Seth James.

January 2006

Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (leaves 92-104).

Aspergillus fumigatus F-box protein Fbx15 functions are dependent on its nuclear localisation signals and are partially conserved between A. fumigatus and A. nidulans

Abelmann, Anja

16 March 2020

No description available.

570

Biologie (PPN619462639)

Investigation into the regulatory mechanism of BRCA2 stability

Gruber, Claudia

January 2013

Inherited mutations in the BRCA2 gene predispose individuals to the development of breast and ovarian cancers. The BRCA2 protein plays a fundamental role in the repair of DNA double strand breaks by homologous recombination (HR). BRCA2 mediates the recruitment of the RAD51 recombinase to DNA damage sites, which in turn promotes homologous pairing and strand exchange during HR. It has been reported that increased BRCA2 mRNA levels correlate with poor cancer prognosis, and recently it has been shown that increased levels of BRCA2 suppress HR. As HR is regulated through the cell cycle and can only be employed during S and G2 phases of the cell cycle, in this study, the cell cycle-dependent regulation of BRCA2, as a key player of HR, was investigated. In this study I report that BRCA2 stability is regulated by the ubiquitin-proteasome system (UPS), which has become increasingly evident as an important regulator of DNA repair. In line with this, I found that BRCA2 can be ubiquitylated in vivo and that it interacts with proteins of the UPS. Interestingly, I observed that BRCA2 levels and its ubiquitylation status change during the cell cycle. Using a siRNA-based approach, I identified a candidate E3 ubiquitin ligase, the SCF^FBXW7 complex, which is also a known major cell cycle regulator. siRNA-mediated knockdown of FBXW7 led to stabilization of BRCA2 and overexpression of FBXW7 resulted in BRCA2 ubiquitylation in vivo. Furthermore, I have refined the regions that the SCF^FBXW7 interacts with on BRCA2, which likely occurs in a phosphorylation-dependent manner. Taken together, these observations suggest that BRCA2 stability is regulated by the UPS in a cell cycle-dependent manner, which may be an important regulatory mechanism for BRCA2 function.

612

Investigating The Roles Of Micrornas In Biotic Stress Responses And Functional Characterization Of A Novel Ztl-type F-box Protein Via Virus Induced Gene Silencing

Dagdas, Yasin Fatih

01 June 2009

Barley and wheat are the two most important crop species in Turkey. Molecular studies for increasing crop yield of these species are very important for the economic benefits of Turkey. Powdery mildew and yellow rust are the two main pathogens, infecting barley and wheat, respectively in our country and causing a great amount of yield loss each year. Till now, classical genetics studies were performed in order to develop resistant barley and wheat cultivars, but these studies have not been succesful. Therefore, molecular plant-pathogen interactions studies are starting to become the new tool to fight against pathogens. In this thesis, two important aspects of plant microbe interactions were investigated. In the first part, the role of microRNAs (miRNAs) in powdery mildew-barley pathosysytem, and yellow rust-wheat pathosystem were studied. The expression levels of miRNAs and their putative targets were investigated via miRNA microarray analysis and qRT-PCR, respectively, in response to virulent and avirulent pathogen infections. These data were used to establish a new model for powdery mildew-barley and yellow rust-wheat pathosystems. In the second part, functional analysis of a novel F-box gene, which was a ZTL-type F-box, was performed by using Barley Stripe Mosaic Virus mediated Virus Induced Gene Silencing. This F-box gene (HvDRF) (Hordeum vulgare Disease Related F-box) was induced upon yellow rust infection and we studied its role in powdery mildew infection. The results confirmed HvDRF as a positive regulator of race specific immunity and enlarged the roles of ZTL-type F-box proteins to biotic stress responses.

QH Methods of Research, Technique 324

Caractérisation biochimique et moléculaire du complexe SCF (SKP1-CULLIN-FBOX) chez le blé tendre

El Beji, Imen

18 July 2011

Les modifications post-traductionnelles des protéines constituent un niveau crucial de régulation de l'expression des gènes. Parmi elles, la conjugaison peptidique impliquant l'ubiquitine intervient entre autre dans la régulation de la stabilité protéique. La fixation de ce peptide de 76 acides aminés, extrêmement conservé, sous forme de chaîne de polyubiquitine, nécessite l'intervention de trois enzymes (E1, E2 et E3) et constitue un signal de dégradation de la protéine ainsi modifiée. Cette voie de régulation intervient dans de très nombreux processus biologiques. Les complexes SCF sont impliqués dans la voie de protéolyse ciblée. Ils représentent l' une des classes les plus fréquentes d'ubiquitine ligase E3 et ils sont composés de quatre sous-unités (Rbx, Cullin, SKP1, et F-box). La structure et la fonction des complexes SCF, ont été étudiées chez la levure, l'Homme et la plante modèle A. thaliana. Cependant, peu de travaux ont été réalisés chez des plantes cultivées, en particulier les céréales, telles que le blé. Cinq gènes codant pour la sous-unité Skp1 (TSK1, TSK3, TSK6, TSK11 et TSK16), cinq gènes codant pour la sous-unité F-box (ZTL, ATFBL5, EBF, TIR1 et ABA-T), un gène codant pour la sous-unité Cullin1 et un gène codant pour la protéine RBX du complexe SCF du blé, ont été isolés et clonés. Les différents tests d'interaction entre les quatre sous-unités du complexe SCF ont été réalisés par la méthode du double-hybride dans la levure en utilisant la technologie Gateway. Ces études ont montré que les deux protéines, TSK1 et TSK3, fixent spécifiquement différentes sous-unités F-box. Parallèlement, nous avons montré que la protéine TSK11 représente une structure particulière. Des études d'insertion/délétion sur la protéine TSK11 ont permis d'identifier un nouveau domaine indispensable à l'interaction. Les analyses par PCR semi-quantitative des différents gènes codant pour la sous-unité Skp1, dans trois tissus différents (feuille tige et racine), ont mis en évidence une expression constitutive des gènes TSK3, TSK6 et TSK11. Tandis que les gènes TSK1 et TSK16 sont exprimés préférentiellement dans les racines. Les analyses par PCR semi-quantitative sur des plantules de blé à différents stades de développement, ont mis en évidence une surexpression du gène TSK11 au moment de la floraison. Ce qui suggère que TSK11 est probablement un équivalent fonctionnel d'ASK1 chez Arabidopsis thaliana.

Ubiquitine Ligase E3

Complexe SCF

Triticum aestivum

TSKs

F-box

Double-hybride dans la levure

SCF-mediated degradation of the two translational regulators, CPB-3 and GLD-1, during oogenesis in C. elegans

Kisielnicka, Edyta

17 April 2018

The development of an organism and its adult homeostasis rely on regulatory mechanisms that control the underlying gene expression programs. In certain biological contexts, such as germ cell development, gene expression regulation is largely executed at the post-­‐transcriptional level. This relies on RNA-­‐binding proteins (RBPs), whose activity and expression are also heavily controlled. While the RNA-­‐binding potential of RBPs is currently of intense scrutiny, surprisingly little is known to date about the molecular mechanisms that control RNA-­‐binding proteins abundance in the context of germ cell development. This work identifies the molecular mechanisms that shape expression patterns of two evolutionarily conserved RNA-­‐binding proteins, CPB-­‐3 and GLD-­‐ 1, which belong to CPEB and STAR protein family, respectively. By focusing on their regulation in the C. elegans germ line, this work reveals an involvement of the proteasome in reducing levels of CPB-­‐3/CPEB and GLD-­‐1/STAR at the pachytene-­‐to-­‐diplotene transition during meiotic prophase I. Furthermore, it documents that CPB-­‐3 and GLD-­‐1 are targeted to proteasomal degradation by a conserved SCF ubiquitin ligase complex that utilises SEL-­‐10/Fbxw7 as a substrate recognition subunit. Importantly, destabilisation of both RBPs is likely triggered by their phosphorylation, which is regulated by the mitogen-­‐activated protein kinase, MPK-­‐1, and restricted to the meiotic timepoint of pachytene exit. Lastly, this work investigates the potential consequences of target mRNA regulation upon delayed RBP degradation. Altogether, the collected data characterise a molecular pathway of CPEB and STAR protein turnover, and suggest that MPK-­‐1 signaling may couple RBP-­‐mediated regulation of gene expression to progression through meiosis during oogenesis.

MAPK

Meiosis

Keimzellen

C. elegans

Translation

ERK kinase signaling

RNA-binding proteins

F-box proteins

germ cell development

ddc:570

rvk:WG 1900

SCF-mediated degradation of the two translational regulators, CPB-3 and GLD-1, during oogenesis in C. elegans

Kisielnicka, Edyta

05 August 2017

The development of an organism and its adult homeostasis rely on regulatory mechanisms that control the underlying gene expression programs. In certain biological contexts, such as germ cell development, gene expression regulation is largely executed at the post-­‐transcriptional level. This relies on RNA-­‐binding proteins (RBPs), whose activity and expression are also heavily controlled. While the RNA-­‐binding potential of RBPs is currently of intense scrutiny, surprisingly little is known to date about the molecular mechanisms that control RNA-­‐binding proteins abundance in the context of germ cell development. This work identifies the molecular mechanisms that shape expression patterns of two evolutionarily conserved RNA-­‐binding proteins, CPB-­‐3 and GLD-­‐ 1, which belong to CPEB and STAR protein family, respectively. By focusing on their regulation in the C. elegans germ line, this work reveals an involvement of the proteasome in reducing levels of CPB-­‐3/CPEB and GLD-­‐1/STAR at the pachytene-­‐to-­‐diplotene transition during meiotic prophase I. Furthermore, it documents that CPB-­‐3 and GLD-­‐1 are targeted to proteasomal degradation by a conserved SCF ubiquitin ligase complex that utilises SEL-­‐10/Fbxw7 as a substrate recognition subunit. Importantly, destabilisation of both RBPs is likely triggered by their phosphorylation, which is regulated by the mitogen-­‐activated protein kinase, MPK-­‐1, and restricted to the meiotic timepoint of pachytene exit. Lastly, this work investigates the potential consequences of target mRNA regulation upon delayed RBP degradation. Altogether, the collected data characterise a molecular pathway of CPEB and STAR protein turnover, and suggest that MPK-­‐1 signaling may couple RBP-­‐mediated regulation of gene expression to progression through meiosis during oogenesis.

info:eu-repo/classification/ddc/570

ddc:570

Destinée des S-RNases dans les tubes polliniques lors des croisements compatibles et incompatibles

Boivin, Nicolas

08 1900

L’auto-incompatibilité (AI) est la capacité génétiquement déterminée d’une plante fertile de rejeter son propre pollen. Chez les Solanacées l’AI dépend des éléments d’un locus fort complexe (locus S) multigénique. L’élément du locus-S exprimé dans le pistil est une ribonucléase (S-RNase) dont le rôle est de dégrader l’ARN chez le pollen self, tandis que l’élément du locus S exprimé dans le pollen est un ensemble de protéines du type F-box, qui sont normalement impliquées dans la dégradation des protéines. Cependant, comment les S-RNases self restent actives lors des croisements incompatibles et comment les S-RNases non-self sont inactivées lors des croisements compatibles ce n’est encore pas clair. Un modèle propose que les S-RNases non-self soient dégradées lors des croisements compatibles. Un autre modèle propose que toutes les S-RNases, self et non-self, soient d'abord séquestrées à l’intérieur d’une vacuole, et elles y resteraient lors des croisements compatibles. Lors de croisements incompatibles, par contre, elles seraient relâchées dans le cytoplasme, où elles pourront exercer leur action cytotoxique. Notre étude tente de répondre à ces questions. Notamment, nous cherchons à mettre en évidence la localisation vacuolaire et/ou cytoplasmique des S-RNases et leur concentration par immunolocalisation, en utilisant un anticorps ciblant la S11-RNase de Solanum chacoense et la microcopie électronique à transmission. Nos résultats montrent que la densité de marquage observée pour les S-RNases cytoplasmiques est significativement plus haute dans les tubes incompatibles que dans ceux compatibles ce qui nous indique que pour qu’un tube pollinique soit compatible il doit contenir une faible densité de S-RNase cytoplasmique. / Self-incompatibility (SI) is a widespread genetic device used by flowering plants to reject their own pollen, and thus to avoid inbreeding. This cell-cell recognition mechanism is mediated by molecular interactions between gene products expressed in the pollen and those expressed in specialized cells of the pistil. The genetic determinants of the system are produced from a highly complex multigenic S-locus with multiple S-haplotypes, although other genes outside the S-locus also contribute to the phenomenon in a non-allele specific manner. SI discriminates between self and non-self pollen, as the former will be rejected (incompatible cross), whereas the latter will be allowed to accomplish fertilization (compatible cross). In the Solanaceae (to which Solanum chacoense belongs) the pistillar determinant to SI is an extremely polymorphic stylar extracellular S-RNase, whereas the pollen determinant involves the collaborative action of several members of the F-box family (SLF or S-locus F-box). This has led to the hypothesis that during compatible crosses, ubiquitin-mediated degradation of non-self S-RNases takes place (degradation model). However, it has also been found that non-self S-RNases appear to be sequestered in the vacuole during compatible crosses (sequestration model). The objective of our study was to discriminate between these two models by using immunolocalization techniques and transmission electron microscopy. We have found that the concentration of S-RNases is significantly higher in incompatible pollen tubes than in compatible ones.

Auto-incompatibilité gamétophytique

Solanum chacoense

S-RNase

Protéine F-box du Locus-S

Tube pollinique

Immunohistochimie

Dégradation protéique

Accumulation de S-RNase

gametophytic self-incompatibility

Solanum chacoense

S-RNase

S-locus F-box

Pollen tube

Immunolocalization

Ubiquitin-mediated degradation

S-RNase accumulation

Destinée des S-RNases dans les tubes polliniques lors des croisements compatibles et incompatibles

Boivin, Nicolas

08 1900

L’auto-incompatibilité (AI) est la capacité génétiquement déterminée d’une plante fertile de rejeter son propre pollen. Chez les Solanacées l’AI dépend des éléments d’un locus fort complexe (locus S) multigénique. L’élément du locus-S exprimé dans le pistil est une ribonucléase (S-RNase) dont le rôle est de dégrader l’ARN chez le pollen self, tandis que l’élément du locus S exprimé dans le pollen est un ensemble de protéines du type F-box, qui sont normalement impliquées dans la dégradation des protéines. Cependant, comment les S-RNases self restent actives lors des croisements incompatibles et comment les S-RNases non-self sont inactivées lors des croisements compatibles ce n’est encore pas clair. Un modèle propose que les S-RNases non-self soient dégradées lors des croisements compatibles. Un autre modèle propose que toutes les S-RNases, self et non-self, soient d'abord séquestrées à l’intérieur d’une vacuole, et elles y resteraient lors des croisements compatibles. Lors de croisements incompatibles, par contre, elles seraient relâchées dans le cytoplasme, où elles pourront exercer leur action cytotoxique. Notre étude tente de répondre à ces questions. Notamment, nous cherchons à mettre en évidence la localisation vacuolaire et/ou cytoplasmique des S-RNases et leur concentration par immunolocalisation, en utilisant un anticorps ciblant la S11-RNase de Solanum chacoense et la microcopie électronique à transmission. Nos résultats montrent que la densité de marquage observée pour les S-RNases cytoplasmiques est significativement plus haute dans les tubes incompatibles que dans ceux compatibles ce qui nous indique que pour qu’un tube pollinique soit compatible il doit contenir une faible densité de S-RNase cytoplasmique. / Self-incompatibility (SI) is a widespread genetic device used by flowering plants to reject their own pollen, and thus to avoid inbreeding. This cell-cell recognition mechanism is mediated by molecular interactions between gene products expressed in the pollen and those expressed in specialized cells of the pistil. The genetic determinants of the system are produced from a highly complex multigenic S-locus with multiple S-haplotypes, although other genes outside the S-locus also contribute to the phenomenon in a non-allele specific manner. SI discriminates between self and non-self pollen, as the former will be rejected (incompatible cross), whereas the latter will be allowed to accomplish fertilization (compatible cross). In the Solanaceae (to which Solanum chacoense belongs) the pistillar determinant to SI is an extremely polymorphic stylar extracellular S-RNase, whereas the pollen determinant involves the collaborative action of several members of the F-box family (SLF or S-locus F-box). This has led to the hypothesis that during compatible crosses, ubiquitin-mediated degradation of non-self S-RNases takes place (degradation model). However, it has also been found that non-self S-RNases appear to be sequestered in the vacuole during compatible crosses (sequestration model). The objective of our study was to discriminate between these two models by using immunolocalization techniques and transmission electron microscopy. We have found that the concentration of S-RNases is significantly higher in incompatible pollen tubes than in compatible ones.

Auto-incompatibilité gamétophytique

Solanum chacoense

S-RNase

Protéine F-box du Locus-S

Tube pollinique

Immunohistochimie

Dégradation protéique

Accumulation de S-RNase

gametophytic self-incompatibility

Solanum chacoense

S-RNase

S-locus F-box

Pollen tube

Immunolocalization

Ubiquitin-mediated degradation

S-RNase accumulation