Developmental relationships in the function of pea root plastids

Li, Hongping, 1967-

January 2000

No description available.

Peas -- Roots -- Physiology.

Plastids -- Composition.

Fatty acids -- Metabolism.

Plant lipids -- Synthesis.

Fatty acid and glycerolipid biosynthesis in pea root plastids

Stahl, Richard J. (Richard John)

January 1990

No description available.

Peas -- Roots -- Physiology.

Plastids -- Composition.

Fatty acids -- Metabolism.

Plant lipids -- Synthesis.

Estudo do direcionamento das proteases FtsH plastidiais às membranas dos tilacóides / Study of plastidial FtsH proteases targeting to thylakoid membranes

Rodrigues, Ricardo Augusto de Oliveira

15 June 2011

O complexo FtsH em Arabidopsis, presente nos tilacóides, é formado pelas subunidades FtsH1/FtsH5 (tipo A) e FtsH2/FtsH8 (tipo B). Os tipos A e B apresentam grande identidade em seus domínios maduros, porém nenhuma similaridade é observada na região amino-terminal do peptídeo de trânsito. Em um experimento de importação em cloroplastos isolados, FtsH2 e FtsH5 foram importadas e subsequentemente integradas aos tilacóides através de um mecanismo de processamento em duas etapas que resultou em um domínio lumenal amino-proximal, uma única âncora transmembrânica e um domínio carboxi-proximal estromal. A integração da FtsH2 em tilacóides isolados foi totalmente dependente do gradiente de prótons, enquanto que a integração da FtsH5 foi dependente de NTPs, sugerindo que a inserção na membrana ocorre pelas vias TAT e Sec, respectivamente. Tal observação foi corroborada por experimentos de competição in-organello e inibição por anticorpos específicos. Os domínios amino-proximais até as âncoras transmembrânicas foram suficientes para a correta integração aos tilacóides. A região madura da FtsH2 apresentou incompatibilidade com a maquinaria Sec, como demonstrado pela troca de peptídeos de trânsito. A incompatibilidade não parece ser determinada por qualquer elemento específico da FtsH2, uma vez que nenhum domínio isolado apresentou incompatibilidade com a via Sec de transporte. Tal fato sugere uma incompatibilidade estrutural que requer a FtsH2 intacta. A descoberta que as subunidades FtsH do tipo A e B, que apresentam grande identidade e usam diferentes vias de integração para formar o mesmo complexo multimérico é uma observação nova e interessante para o estudo da biogênese de proteínas de membranas. O mecanismo de regulação que governa a atividade do complexo FtsH em Arabidopsis é ainda desconhecido, entretanto é proposta a existência de fatores adicionais. Dessa forma, a proteína plastidial FtsH de Arabidopsis foi usada como isca em um rastreamento por duplohíbrido de levedura. O rastreamento resultou em 48 colônias que ativaram os genes repórteres histidina e adenina. Entre todos os cDNAs sequenciados, foi encontrado um candidato em potencial denominado FIP (FtsH5 Interacting Protein). Experimentos GST Pull-Down também indicam uma interação entre FtsH5 e FIP. O precursor FIP radioativo foi incubado com cloroplastos de ervilha. Após a incubação, os cloroplastos foram lisados e separados em estroma e tilacóides. FIP permaneceu associada exclusivamente à fração membranosa dos tilacóides. A inserção na membrana foi verificada através da resistência ao tratamento com álcali e o tratamento dos tilacóides com protease resultou em um fragmento protegido, característico de proteínas inseridas na membrana. A construção FtsH5::GFP transformada em Nicotiana tabacum resultou no direcionamento do gene quimérico aos cloroplastos. Dessa forma, assim como FtsH5, FIP é uma proteína plastidial que está localizada na membrana dos tilacóides. Géis nativos utilizando FIP radioativa mostram que ela está associada a um complexo de aproximadamente 450 kDa, que é o tamanho esperado para o complexo tilacoidal FtsH em Arabidopsis. Como as proteínas FtsH apresentam tanto o domínio ATPase quanto protease, acreditamos que FIP pode de alguma forma modular a atividade do complexo FtsH nos tilacóides. / The Arabidopsis thylakoid FtsH protease complex is composed of FtsH1/FtsH5 (type A) and FtsH2/FtsH8 (type B) subunits. Type A and type B subunits display a high degree of sequence identity throughout their mature domains, but no similarity in their amino-terminal targeting peptide regions. In chloroplast import assays, FtsH2 and FtsH5 were imported and subsequently integrated into thylakoids by a two-step processing mechanism that resulted in an amino-proximal lumenal domain, a single transmembrane anchor, and a carboxyl proximal stromal domain. FtsH2 integration into washed thylakoids was entirely dependent on the proton gradient, whereas FtsH5 integration was dependent on NTPs, suggesting their integration by Tat and Sec pathways, respectively. This finding was corroborated by in organello competition and by antibody inhibition experiments. The amino proximal domains through the transmembrane anchors were sufficient for proper integration. The mature FtsH2 protein was found to be incompatible with the Sec machinery as determined with targeting peptide-swapping experiments. Incompatibility does not appear to be determined by any specific element in the FtsH2 domain as no single domain was incompatible with Sec transport. This suggests an incompatible structure that requires the intact FtsH2. That the highly homologous type A and type B subunits of the same multimeric complex use different integration pathways is a striking example of the notion that membrane insertion pathways have evolved to accommodate structural features of their respective substrates. The regulation mechanism which governs the Arabidopsis FtsH complexs activity is still unknown, but it is proposed the presence of additional factors. For this reason, the plastidial Arabidopsis FtsH5 was used as bait in a yeast two hybrid screening. The screening resulted in 48 colonies that activated the histidine and adenine reporter genes. Among all the sequenced cDNAs we have found a potential candidate named FIP (FtsH5 Interacting Protein). GST Pull-Down experiments also indicate an interaction between FtsH5 and FIP. Radiolabeled FIP was incubated with intact isolated chloroplasts. After incubation, intact chloroplasts were lysated and separated into stroma and thylakoids. FIP remained associated exclusively with the thylakoid membrane fraction. The insertion into membrane was verified throughout resistance to alkali treatment and the thylakoid protease treated fraction resulted in a protected fragment, characteristic of membrane-inserted proteins. Agroinfiltrated Nicotiana tabacum leaves with a FtsH5::GFP construct resulted that the chimeric gene was targeted to chloroplasts. Thus, as FtsH5, FIP is a plastidial protein which is located into thylakoid membrane. Blue native gels using radiolabeled FIP protein show that it runs associated with a complex around 450 kDa, which is the expected size for the Arabidopsis FtsH thylakoidal complex. As FtsH proteins present both ATPase and protease domains, we believe that FIP can somehow modulates the activity of the thylakoidal FtsH complex.

Clonagem

Cloning

Cloroplastos vegetais

Expressão gênica

Gene expression

Membranas vegetais

Plant chloroplasts

Plant membranes

Plant proteins.

Plastídeos

Plastids

Proteínas de plantas.

Estudo do direcionamento das proteases FtsH plastidiais às membranas dos tilacóides / Study of plastidial FtsH proteases targeting to thylakoid membranes

Ricardo Augusto de Oliveira Rodrigues

15 June 2011

O complexo FtsH em Arabidopsis, presente nos tilacóides, é formado pelas subunidades FtsH1/FtsH5 (tipo A) e FtsH2/FtsH8 (tipo B). Os tipos A e B apresentam grande identidade em seus domínios maduros, porém nenhuma similaridade é observada na região amino-terminal do peptídeo de trânsito. Em um experimento de importação em cloroplastos isolados, FtsH2 e FtsH5 foram importadas e subsequentemente integradas aos tilacóides através de um mecanismo de processamento em duas etapas que resultou em um domínio lumenal amino-proximal, uma única âncora transmembrânica e um domínio carboxi-proximal estromal. A integração da FtsH2 em tilacóides isolados foi totalmente dependente do gradiente de prótons, enquanto que a integração da FtsH5 foi dependente de NTPs, sugerindo que a inserção na membrana ocorre pelas vias TAT e Sec, respectivamente. Tal observação foi corroborada por experimentos de competição in-organello e inibição por anticorpos específicos. Os domínios amino-proximais até as âncoras transmembrânicas foram suficientes para a correta integração aos tilacóides. A região madura da FtsH2 apresentou incompatibilidade com a maquinaria Sec, como demonstrado pela troca de peptídeos de trânsito. A incompatibilidade não parece ser determinada por qualquer elemento específico da FtsH2, uma vez que nenhum domínio isolado apresentou incompatibilidade com a via Sec de transporte. Tal fato sugere uma incompatibilidade estrutural que requer a FtsH2 intacta. A descoberta que as subunidades FtsH do tipo A e B, que apresentam grande identidade e usam diferentes vias de integração para formar o mesmo complexo multimérico é uma observação nova e interessante para o estudo da biogênese de proteínas de membranas. O mecanismo de regulação que governa a atividade do complexo FtsH em Arabidopsis é ainda desconhecido, entretanto é proposta a existência de fatores adicionais. Dessa forma, a proteína plastidial FtsH de Arabidopsis foi usada como isca em um rastreamento por duplohíbrido de levedura. O rastreamento resultou em 48 colônias que ativaram os genes repórteres histidina e adenina. Entre todos os cDNAs sequenciados, foi encontrado um candidato em potencial denominado FIP (FtsH5 Interacting Protein). Experimentos GST Pull-Down também indicam uma interação entre FtsH5 e FIP. O precursor FIP radioativo foi incubado com cloroplastos de ervilha. Após a incubação, os cloroplastos foram lisados e separados em estroma e tilacóides. FIP permaneceu associada exclusivamente à fração membranosa dos tilacóides. A inserção na membrana foi verificada através da resistência ao tratamento com álcali e o tratamento dos tilacóides com protease resultou em um fragmento protegido, característico de proteínas inseridas na membrana. A construção FtsH5::GFP transformada em Nicotiana tabacum resultou no direcionamento do gene quimérico aos cloroplastos. Dessa forma, assim como FtsH5, FIP é uma proteína plastidial que está localizada na membrana dos tilacóides. Géis nativos utilizando FIP radioativa mostram que ela está associada a um complexo de aproximadamente 450 kDa, que é o tamanho esperado para o complexo tilacoidal FtsH em Arabidopsis. Como as proteínas FtsH apresentam tanto o domínio ATPase quanto protease, acreditamos que FIP pode de alguma forma modular a atividade do complexo FtsH nos tilacóides. / The Arabidopsis thylakoid FtsH protease complex is composed of FtsH1/FtsH5 (type A) and FtsH2/FtsH8 (type B) subunits. Type A and type B subunits display a high degree of sequence identity throughout their mature domains, but no similarity in their amino-terminal targeting peptide regions. In chloroplast import assays, FtsH2 and FtsH5 were imported and subsequently integrated into thylakoids by a two-step processing mechanism that resulted in an amino-proximal lumenal domain, a single transmembrane anchor, and a carboxyl proximal stromal domain. FtsH2 integration into washed thylakoids was entirely dependent on the proton gradient, whereas FtsH5 integration was dependent on NTPs, suggesting their integration by Tat and Sec pathways, respectively. This finding was corroborated by in organello competition and by antibody inhibition experiments. The amino proximal domains through the transmembrane anchors were sufficient for proper integration. The mature FtsH2 protein was found to be incompatible with the Sec machinery as determined with targeting peptide-swapping experiments. Incompatibility does not appear to be determined by any specific element in the FtsH2 domain as no single domain was incompatible with Sec transport. This suggests an incompatible structure that requires the intact FtsH2. That the highly homologous type A and type B subunits of the same multimeric complex use different integration pathways is a striking example of the notion that membrane insertion pathways have evolved to accommodate structural features of their respective substrates. The regulation mechanism which governs the Arabidopsis FtsH complexs activity is still unknown, but it is proposed the presence of additional factors. For this reason, the plastidial Arabidopsis FtsH5 was used as bait in a yeast two hybrid screening. The screening resulted in 48 colonies that activated the histidine and adenine reporter genes. Among all the sequenced cDNAs we have found a potential candidate named FIP (FtsH5 Interacting Protein). GST Pull-Down experiments also indicate an interaction between FtsH5 and FIP. Radiolabeled FIP was incubated with intact isolated chloroplasts. After incubation, intact chloroplasts were lysated and separated into stroma and thylakoids. FIP remained associated exclusively with the thylakoid membrane fraction. The insertion into membrane was verified throughout resistance to alkali treatment and the thylakoid protease treated fraction resulted in a protected fragment, characteristic of membrane-inserted proteins. Agroinfiltrated Nicotiana tabacum leaves with a FtsH5::GFP construct resulted that the chimeric gene was targeted to chloroplasts. Thus, as FtsH5, FIP is a plastidial protein which is located into thylakoid membrane. Blue native gels using radiolabeled FIP protein show that it runs associated with a complex around 450 kDa, which is the expected size for the Arabidopsis FtsH thylakoidal complex. As FtsH proteins present both ATPase and protease domains, we believe that FIP can somehow modulates the activity of the thylakoidal FtsH complex.

Clonagem

Cloroplastos vegetais

Expressão gênica

Membranas vegetais

Plastídeos

Proteínas de plantas.

Cloning

Gene expression

Plant chloroplasts

Plant membranes

Plant proteins.

Plastids

Phagenähnliche RNA-Polymerasen

Swiatecka-Hagenbruch, Monika

26 May 2009

Chloroplasten höherer Pflanzen haben kleine Genome. Trotzdem ist ihre Transkriptionsmaschinerie sehr komplex. Plastidäre Gene werden von plastidenkodierten (PEP) und kernkodierten RNA-Polymerasen (NEP) transkribiert. In der vorliegenden Arbeit wurden Promotoren plastidärer Gene und Operons von Arabidopsis thaliana charakterisiert. Zur Unterscheidung zwischen NEP- und PEP-Promotoren wurden erstmals spectinomycinbehandelte, chlorophylldefiziente Arabidopsis-Pflanzen mit fehlender PEP-Aktivität verwendet. Obwohl für einige Gene auch einzelne Promotoren lokalisiert wurden, wird die Transkription der meisten plastidären Gene und Operons an multiplen Promotoren initiiert. Der Vergleich plastidärer Promotoren von Tabak und Arabidopsis zeigte eine hohe Vielfältigkeit der Promotornutzung, die möglicherweise auch in anderen höheren Pflanzen vorkommt. Dabei stellt die individuelle Promotornutzung eine speziesspezifische Kontrollmöglichkeit der plastidären Genexpression dar. Das Kerngenom von Arabidopsis beinhaltet zwei Kandidatengene der NEP, RpoTp und RpoTmp, welche Phagentyp-RNA-Polymerasen kodieren. In der vorliegenden Arbeit wurde die Wirkung veränderter RpoTp-Aktivität auf die Nutzung von NEP- und PEP-Promotoren in transgenen Arabidopsis-Pflanzen mit verminderter und fehlender RpoTp-Aktivität untersucht. Im Keimlingsstadium konnten Unterschiede in der Promotornutzung zwischen Wildtyp und Mutanten beobachtet werden. Fast alle NEP-Promotoren wurden in Pflanzen mit verringerter oder fehlender RpoTp-Aktivität genutzt. Dabei zeigten nur einige von ihnen eine geringere Aktivität, andere wiederum waren sogar verstärkt aktiv. Der starke NEP-Promotor des essentiellen ycf1 Gens wurde in jungen Keimlingen ohne funktionelle RpoTp nicht genutzt. Die Ergebnisse zeigen, dass NEP gemeinsam von beiden Phagentyp-RNA-Polymerasen RpoTp und RpoTmp repräsentiert wird und dass beide sowohl eine überlappende, als auch eine spezifische Rolle in der Transkription plastidärer Gene innehaben. / Although chloroplasts of higher plants have small genomes, their transcription machinery is very complex. Plastid genes of higher plants are transcribed by the plastid-encoded plastid RNA polymerase PEP and the nuclear-encoded plastid RNA polymerases NEP. Here, promoters of plastid genes and operons have been characterized in Arabidopsis thaliana. For the first time spectinomycin-treated, chlorophyll-deficient Arabidopsis plants lacking PEP activity have been used to discriminate between NEP and PEP promoters. Although there are plastid genes that are transcribed from a single promoter, the transcription of plastid genes and operons by multiple promoters seems to be a common feature. Comparison of plastid promoters from tobacco and Arabidopsis revealed a high diversity, which my also apply to other plants. The diversity in individual promoter usage in different plants suggests that there are species-specific solutions for attaining control over gene expression in plastids. The nuclear genome of Arabidopsis contains two candidate genes for NEP transcription activity, RpoTp and RpoTmp, both coding for phage-type RNA polymerases. In this study the usage of NEP and PEP promoters has been analysed in transgenic Arabidopsis plants with reduced and lacking RpoTp activity. Differences in promoter usage between wild type and mutant plants were most obvious early in development. Nearly all NEP promoters were active in plants with low or lacking RpoTp activity, though certain promoters showed reduced or even increased usage. The strong NEP promoter of the essential ycf1 gene was not transcribed in young seedlings without functional RpoTp. These results provide evidence for NEP being represented by two phage-type RNA polymerases RpoTp and RpoTmp that have overlapping as well as specific functions in the transcription of plastid genes.

Promotor

Transkription

Plastiden

Phagentyp-RNA-Polymerasen

NEP-Transkriptionsaktivität

Plastids

Promoters

Transcription

Phage-type RNA-Polymerases

NEP transcription activity

580 Pflanzen (Botanik)

32 Biologie

WG 1800

ddc:580

Caracterização de plantas transgênicas de tabaco (Nicotiana tabacum L.) que expressam o gene Lhcb1*2 de ervilha quanto aos impactos no desenvolvimento dos cloroplastos e formação do fotossistema II. / Characterization of transgenic tobacco plants (Nicotiana tabacum L.) which express the pea lhcb1*2 gene, upon chloroplast development and assembly of the photossystem II.

Cordeiro, Raqueline Cunha

18 November 2004

A produção vegetal é dependente do processo fotossintético. As técnicas de biologia molecular e transformação genética de plantas trouxeram boas perspectivas para a alteração do metabolismo fotossintético. Plantas transgênicas de tabaco (Nicotiana tabacum, L.) que superexpressam o gene quimérico Lhcb1*2 de ervilha têm sido estudadas por apresentarem uma série de alterações no desenvolvimento e no metabolismo fotossintético, em relação à linhagem selvagem. Vários autores observaram mudanças morfológicas, fisiológicas, bioquímicas e adaptativas que favorecem essas plantas em diversas condições de cultivo. O objetivo desse trabalho foi o de avaliar o impacto da superexpressão desse gene na formação plastidial de plântulas de tabaco germinadas e mantidas no escuro por sete dias e depois transferidas à luz, com coletas periódicas de 0, 6, 18 e 120 horas pós-iluminação. O desenvolvimento plastidial, avaliado por microscopia de luz, mostra um provável adiantamento na formação dos cloroplastos dos materiais vegetais transgênicos (TR1 e TR2) em relação à selvagem (WT). A análise de ultraestrutura dos plastídios por microscopia eletrônica de transmissão, demostrou um real adiantamento na formação dos cloroplastos maduros nas duas linhagens transgênicas A análise de Western blot confimou a presença de proteínas específicas do fotossistema II (Lhcb 1-2 e D1). Este fato implica que a montagem do aparato fotossintético é antecipada nos transgênicos, assim como o desenvolvimento morfológico e estrutural observado nos plastídios. / The vegetal production is strictly dependent on the photosynthetic process. Techniques of molecular biology and genetic transformation of plants brought good perspectives for the alteration of the photosynthetic metabolism. Transgenic tobacco plants (Nicotiana tabacum, L.) which express the chimeric pea Lhcb1*2 gene were pbtained and presenta series of alterations on development and photosynthetic metabolism in relation to the wild type. Previous analysis have demonstrated morphological, physiological, biochemical and adaptative changes that favour these transgenic lines in various conditions of culture. The aim of this work was to evaluate the impact of the expression of this gene in the plastid formation, of tobacco seedlings. Seeds were germinated and kept in darknes for seven days, and transferred to light. The seedlings were then collected after 0, 6, 18 and 120 hours of exposure to continuous ilumination. The plastidial development evaluated by light microscopy, showed an advanced chloroplast formation of the transgenic lines (TR1 and TR2) in relation to the wild type (WTSR1). The ultrastructural analysis of the plastids by electronic microscopy showed, indeed on advanced formation of mature chloroplasts in the transgenic lines. The Western blot analysis confirmed the presence of two specific proteins (CAB and D1), of the photosystem II. This fact implies that the assembly of the photosynthetic apparatus might occurs earlier in the transgenic lines, as well as the morphological and structural development of the plastids.

electronic microscopy

engenharia genética

fumo

linhagens vegetais

melhoramento genético vegetal

metabolismo fotossintético

microscopia eletrônica

photosynthetic metabolism

planta transgênica

plastídeos

plastids

tobacco

transgenic plants

Caracterização de plantas transgênicas de tabaco (Nicotiana tabacum L.) que expressam o gene Lhcb1*2 de ervilha quanto aos impactos no desenvolvimento dos cloroplastos e formação do fotossistema II. / Characterization of transgenic tobacco plants (Nicotiana tabacum L.) which express the pea lhcb1*2 gene, upon chloroplast development and assembly of the photossystem II.

Raqueline Cunha Cordeiro

18 November 2004

A produção vegetal é dependente do processo fotossintético. As técnicas de biologia molecular e transformação genética de plantas trouxeram boas perspectivas para a alteração do metabolismo fotossintético. Plantas transgênicas de tabaco (Nicotiana tabacum, L.) que superexpressam o gene quimérico Lhcb1*2 de ervilha têm sido estudadas por apresentarem uma série de alterações no desenvolvimento e no metabolismo fotossintético, em relação à linhagem selvagem. Vários autores observaram mudanças morfológicas, fisiológicas, bioquímicas e adaptativas que favorecem essas plantas em diversas condições de cultivo. O objetivo desse trabalho foi o de avaliar o impacto da superexpressão desse gene na formação plastidial de plântulas de tabaco germinadas e mantidas no escuro por sete dias e depois transferidas à luz, com coletas periódicas de 0, 6, 18 e 120 horas pós-iluminação. O desenvolvimento plastidial, avaliado por microscopia de luz, mostra um provável adiantamento na formação dos cloroplastos dos materiais vegetais transgênicos (TR1 e TR2) em relação à selvagem (WT). A análise de ultraestrutura dos plastídios por microscopia eletrônica de transmissão, demostrou um real adiantamento na formação dos cloroplastos maduros nas duas linhagens transgênicas A análise de Western blot confimou a presença de proteínas específicas do fotossistema II (Lhcb 1-2 e D1). Este fato implica que a montagem do aparato fotossintético é antecipada nos transgênicos, assim como o desenvolvimento morfológico e estrutural observado nos plastídios. / The vegetal production is strictly dependent on the photosynthetic process. Techniques of molecular biology and genetic transformation of plants brought good perspectives for the alteration of the photosynthetic metabolism. Transgenic tobacco plants (Nicotiana tabacum, L.) which express the chimeric pea Lhcb1*2 gene were pbtained and presenta series of alterations on development and photosynthetic metabolism in relation to the wild type. Previous analysis have demonstrated morphological, physiological, biochemical and adaptative changes that favour these transgenic lines in various conditions of culture. The aim of this work was to evaluate the impact of the expression of this gene in the plastid formation, of tobacco seedlings. Seeds were germinated and kept in darknes for seven days, and transferred to light. The seedlings were then collected after 0, 6, 18 and 120 hours of exposure to continuous ilumination. The plastidial development evaluated by light microscopy, showed an advanced chloroplast formation of the transgenic lines (TR1 and TR2) in relation to the wild type (WTSR1). The ultrastructural analysis of the plastids by electronic microscopy showed, indeed on advanced formation of mature chloroplasts in the transgenic lines. The Western blot analysis confirmed the presence of two specific proteins (CAB and D1), of the photosystem II. This fact implies that the assembly of the photosynthetic apparatus might occurs earlier in the transgenic lines, as well as the morphological and structural development of the plastids.

engenharia genética

fumo

linhagens vegetais

melhoramento genético vegetal

metabolismo fotossintético

microscopia eletrônica

planta transgênica

plastídeos

electronic microscopy

photosynthetic metabolism

plastids

tobacco

transgenic plants

Caractérisation fonctionnelle d'AtLTP2, une protéine de transfert de lipides impliquée dans le contrôle de l'intégrité de la cuticule chez Arabidopsis thaliana / Functional characterization of AtLTP2, a lipid transfer protein involved in the control of cuticle integrity in Arabidopsis thaliana

Jacq, Adélaïde

25 November 2016

La cuticule est une couche hydrophobe déposée à la surface des organes aériens des plantes terrestres. Elle joue de nombreux rôles allant de la résistance face à divers stress biotiques et abiotiques à son implication dans divers processus de développement. Bien que la compréhension de la biosynthèse des composés cuticulaires a considérablement augmenté ces dernières années, les mécanismes de transport de ces lipides cuticulaires à travers la paroi et d'assemblage au sein de la cuticule, sont encore peu caractérisés. Les nsLTPs (non-specific Lipid Transfer Protein), sont codées par une famille multigénique impliquée dans de nombreuses fonctions biologiques. Parmi les rôles proposés pour les nsLTPs, il est supposé depuis longtemps qu'elles pourraient transporter les précurseurs cuticulaires à travers la paroi et ainsi contribuer à la formation de la cuticule. Dans ce travail de thèse, nous nous sommes servis du modèle des hypocotyles étiolés d'A. thaliana afin de caractériser le fonction biologique d'AtLTP2. En effet, AtLTP2 est une protéine de transfert de lipides présente de façon abondante et est la seule représentante des nsLTPs dans le protéome pariétal des hypocotyles étiolés. Nous avons tout d'abord confirmé que l'expression d'AtLTP2 est forte dans les très jeunes stades de développement de la plantule étiolée et est restreinte aux cellules de l'épiderme des organes aériens, sur lesquelles se dépose la cuticule. Conformément aux résultats de protéomique obtenus au préalable, AtLTP2 fusionnée à un marqueur fluorescent est localisée au niveau de la paroi mais également et de façon surprenante au niveau des plastes. Cette remarquable double localisation d'une nsLTP dans la paroi et dans les plastes n'a à ce jour, jamais été décrite. De plus, le mode de transport d'AtLTP2 vers les plastes est particulièrement original puisque la protéine emprunte d'abord la voie de sécrétion avant d'être finalement adressée aux plastes. En analysant l'adressage de différentes versions d'AtLTP2 tronquée, nous avons pu montrer que c'est certainement sa conformation tertiaire qui est cruciale pour sa localisation plastidiale. Par des approches de génétique inverse, nous avons pu montrer que les mutants atltp2 présentaient une augmentation importante de la perméabilité de sa cuticule fortement corrélée à une ultrastructure de l'interface cuticule-paroi très perturbée alors qu'aucun changement dans la composition biochimique de la cuticule n'a été détecté. Ces résultats nous ont permis de proposer un nouveau rôle structural pour AtLTP2, elle interviendrait pour maintenir l'adhésion des deux couches que sont la cuticule hydrophobe et la paroi hydrophile. Ainsi, en maintenant l'intégrité de l'interface entre la cuticule et la paroi, AtLTP2 participerait au maintien de la fonction de barrière cuticulaire limitant les pertes d'eau. De façon intéressante, la double localisation d'AtLTP2 dans la paroi et les plastes nous laisse supposer que d'autres fonctions pourraient être assignées à AtLTP2. L'identification des mécanismes moléculaires mis en jeu dans le maintien de l'homéostasie cuticule-paroi et dans la double localisation d'AtLTP2 constituera un challenge pour de futures recherches visant à toujours mieux identifier les acteurs de la formation de cette barrière protectrice, la cuticule. / The cuticle is a hydrophobic layer that covers the surface of the aerial organs of land plants. The cuticle plays numerous roles in plants from resistance against biotic and abiotic stresses to several developmental processes. Although the understanding of the biosynthesis of cuticle has considerably increased last years, the mechanisms underlying the transport of cuticular lipids through the cell wall and their assembly within the cuticle have been poorly characterized. nsLTPs (non-specific Lipid Transfer Proteins) are encoded by a multigenic family in A. thaliana and are involved in several biological processes. Among the different roles proposed for nsLTPs, it has long been suggested that they could transport cuticular precursor across the cell wall and then could contribute to the cuticle formation, despite the absence of formal evidence for individual members. Here we took advantage of the A. thaliana etiolated hypocotyls model to characterize the biological function of AtLTP2. Indeed, AtLTP2 was found to be abundant and the unique nsLTP member in the cell wall proteome of etiolated hypocotyls. We have first confirmed the high level of AtLTP2 expression during the young developmental stages of etiolated seedlings that was restricted to the epidermal cells of aerial organs, that are covered by the cuticle. In agreement with the cell wall localization determined by previous proteomic studies, we localized AtLTP2 fused to a fluorescent marker to the cell wall, but also and surprisingly to the plastids. This remarkable dual localization in the cell wall and plastids was never described before for a nsLTP. Furthermore, the mechanism of AtLTP2 transport to the plastids was particularly original because AtLTP2 can first undergo import into the ER/ secretory pathway and then sorting to the cell wall and the plastids. By studying the sub-cellular localization of truncated version of AtLTP2, we have shown that its tertiary conformation was crucial for the plastidial localization. By using reverse genetic approaches, we have shown that atltp2 mutants displayed a high increase in cuticle permeability strongly correlated with a deep modification of the ultra-structure at the cuticle-cell wall interface, while no changes in biochemical composition of the cuticle were detected. These results prompt us to suggest a novel structural role for AtLTP2. AtLTP2 could be involved in maintaining the accurate sealing between the hydrophobic cuticle and the hydrophilic underlying cell wall. Then, by preserving the integrity of the cuticle-cell wall interface, AtLTP2 could act on the barrier function of the cuticle limiting water loss. Interestingly, the dual localization to the cell wall and plastids suggested that other functions could be assigned to AtLTP2. The elucidation of the molecular mechanisms by which AtLTP2 establish cell wall-cuticle homeostasis and the exact function of the dual targeting will be challenging tasks in the future to better identify the main actors of the formation of the cuticle.

Arabidopsis thaliana

AtLTP2

Protéine de transfert de lipides

Interface paroi-cuticule

Plastes

Double localisation

Arabidopsis thaliana

AtLTP2

Lipid transfer prtotein

Plastids

Dual localization

Un rôle pour les protéines de la famille Whirly dans le maintien de la stabilité du génome des organelles chez Arabidopsis thaliana

Maréchal, Alexandre

07 1900

Le maintien de la stabilité du génome est essentiel pour la propagation de l’information génétique et pour la croissance et la survie des cellules. Tous les organismes possèdent des systèmes de prévention des dommages et des réarrangements de l’ADN et nos connaissances sur ces processus découlent principalement de l’étude des génomes bactériens et nucléaires. Comparativement peu de choses sont connues sur les systèmes de protection des génomes d’organelles. Cette étude révèle l’importance des protéines liant l’ADN simple-brin de la famille Whirly dans le maintien de la stabilité du génome des organelles de plantes. Nous rapportons que les Whirlies sont requis pour la stabilité du génome plastidique chez Arabidopsis thaliana et Zea mays. L’absence des Whirlies plastidiques favorise une accumulation de molécules rearrangées produites par recombinaison non-homologue médiée par des régions de microhomologie. Ce mécanisme est similaire au “microhomology-mediated break-induced replication” (MMBIR) retrouvé chez les bactéries, la levure et l’humain. Nous montrons également que les organelles de plantes peuvent réparer les bris double-brin en utilisant une voie semblable au MMBIR. La délétion de différents membres de la famille Whirly entraîne une accumulation importante de réarrangements dans le génome des organelles suite à l’induction de bris double-brin. Ces résultats indiquent que les Whirlies sont aussi importants pour la réparation fidèle des génomes d’organelles. En se basant sur des données biologiques et structurales, nous proposons un modèle où les Whirlies modulent la disponibilité de l’ADN simple-brin, régulant ainsi le choix des voies de réparation et permettant le maintien de la stabilité du génome des organelles. Les divers aspects de ce modèle seront testés au cours d’expériences futures ce qui mènera à une meilleure compréhension du maintien de la stabilité du génome des organelles. / Maintenance of genome stability is essential for the accurate propagation of genetic information and for cell growth and survival. Organisms have therefore developed efficient strategies to prevent DNA lesions and rearrangements. Much of the information concerning these strategies has been obtained through the study of bacterial and nuclear genomes. Comparatively little is known about how organelle genomes maintain a stable structure. This study implicates the single-stranded nucleic acid-binding proteins of the Whirly family in the maintenance of plant organelle genome stability. Here we report that the plastid-localized single-stranded DNA binding proteins of the Whirly family are required for plastid genome stability in Arabidopsis thaliana and Zea mays. Absence of plastidial Whirlies favors the accumulation of rearranged molecules that arise through a non-homologous recombination mechanism mediated by regions of microhomology. This mechanism is similar to the microhomology-mediated break-induced replication (MMBIR) described in bacteria, yeast and humans. Additionally we show that plant organelles can repair double-strand breaks using a MMBIR-like pathway. Plants lacking Whirly proteins accumulate elevated levels of microhomology-mediated DNA rearrangements upon double-strand break induction, indicating that Whirlies also contribute to the accurate repair of plant organelle genomes. Using biological and structural data, we propose a working model in which Whirlies modulate the access of repair proteins and complementary DNA to single-stranded regions, thereby regulating the choice of repair pathways and maintaining plant organelle genome stability. The various aspects of this model will be tested in future experiments which should allow a better understanding of the mechanisms underlying genome stability in plant organelles.

Protéines Whirly

plastides

mitochondries

biologie des plantes

stabilité du génome

Whirly proteins

single-stranded nucleic acids

maintenance of genome stability

plant biology

plastids

mitochondria

The transcriptome of barley chloroplasts revealed by deep sequencing

Zhelyazkova, Petya

03 January 2013

Die gegenwärtige Vorstellung von Genexpression in Plastiden leitet sich von der Analyse weniger, individueller Gene ab und ist deshalb noch relativ lückenhaft. In dieser Arbeit sollte daher differenzierende RNA Sequenzierung- eine neue Methode, die zwischen prozessierten und Primärtranskripten unterscheiden kann, verwendet werden, um ein vollständigeres Bild des Transkriptionsprozesses und der RNA Prozessierung von Hordeum vulgare L. (Gerste) Chloroplasten zu erhalten. Plastidengene in höheren Pflanzen können sowohl von einer plastidenkodierten, bakterienähnlichen RNA-Polymerase (PEP), als auch von einer kernkodierten, phagenähnlichen RNA-Polymerase (NEP), die beide unterschiedliche Promotoren erkennen, abgelesen werden. In dieser Arbeit wurde die Verteilung von Transkriptionsstartstellen innerhalb des Plastidengenoms von grünen (reife Chloroplasten; Transkriptionsaktivität von PEP und NEP) und weißen Plastiden (Transkriptionsaktivität von NEP) der Gerstenmutantenlinie albostrians analysiert. Dies führte zu neuen Erkenntnissen bezüglich polymerasenspezifischer Genexpression in Plastiden. Auf Grundlage neuerer Arbeiten wird angenommen, daß nicht kodierende RNAs (ncRNAs) in Chloroplasten vorkommen. Die bisher verwendeten Methoden waren jedoch nicht geeignet, ncRNAs als Primärtranskripte zu identifizieren, die zumindest in Prokaryoten die häufigste Klasse von ncRNAs darstellen. In dieser Arbeit konnte durch dRNA-seq gezeigt werden, daß auch in Plastiden zahlreiche ncRNAs als Primärtranskripte generiert werden. Die wichtigsten Schritte im Prozess der mRNA Reifung in Plastiden sind 5´und 3´ Endformation und intercistronische Prozessierung. Vor Kurzem wurde gezeigt, daß ein PPR (Pentatricopeptide repeat) Protein zur Bildung der Ende von einigen prozessierten Plastiden mRNAs beiträgt, indem es als Hindernis für Exonukleasen wirkt. Mit dieser Arbeit konnte gezeigt werden, daß dies ein genereller Mechanismus zur Bildung prozessierter mRNA-Enden in Chloroplasten ist. / The current view on plastid gene expression is mainly based on the analysis of a few individual genes, and thus it is lacking in comprehensiveness. Here, a novel differential RNA-seq approach, designed to discriminate between primary and processed transcripts, was used to obtain a deeper insight into the plastid transcription and RNA maturation of mature barley (Hordeum vulgare L.) chloroplasts. Transcription in plastids of higher plants is dependent on two different transcription machineries, a plastid-encoded bacterial-type RNA polymerase (PEP) and a nuclear-encoded phage-type RNA polymerase (NEP), which recognize distinct types of promoters. This study provided a thorough investigation into the distribution of transcription start sites within the plastid genome of green (mature chloroplasts; transcription by both PEP and NEP) and white (PEP-deficient plastids; transcription by NEP) plastids of the barley line albostrians. This analysis led to new insights on polymerase specific gene expression in plastids. Recent studies have suggested that non-coding RNAs (ncRNAs) are common in chloroplasts. However, they did not directly detect ncRNAs generated via transcription, the so far most abundant class of known regulatory ncRNAs in bacteria. Here, dRNA-seq analysis of the transcriptome of barley chloroplasts demonstrated the existence of numerous ncRNA generated via transcription of free-standing genes. Major events in plastid mRNA maturation include 5’ and 3’ processed end formation and intercistronic processing. Recently, a PPR (pentatricopeptide repeat) protein was shown to participate in the generation of several plastid mRNA processed ends by serving as a barrier to exonucleases. This study provided evidence for the global impact of this mechanism on processed termini formation in chloroplasts.

Transkription

Plastiden

plastidenkodierte RNA-Polymerase

kernkodierte RNA-Polymerase

nicht kodierende RNAs

mRNA Reifung

transcription

non-coding RNAs

plastids

plastid-encoded RNA polymerase

nuclear-encoded RNA polymerase

mRNA maturation

570 Biowissenschaften, Biologie

32 Biologie

WG 2300

ddc:570