Application of new genomic methods to the characterization of Arabidopsis thaliana photomorphogenesis

Corbett, Robert Wayne

30 October 2006

The ability of plants to not only detect but also adjust to their environment is crucial for their survival. The genes involved in photomorphogenesis – developmental changes in response to light – and their regulation have long been of interest to researchers. While the phytochrome and cryptochrome photoreceptors have been isolated and partially characterized, the downstream components of the light signaling pathway which transmit the perceived light signals and regulate gene expression are still being discovered. A negative regulator of photomorphogenesis, DET1 (de-etiolated 1), was discovered in a mutant screen for plants that develop a light grown phenotype in the dark. DET1 is nuclear localized, but its exact function remains unknown. Two contrasting mechanisms for the role of DET1 in the regulation of gene expression have been proposed based on studies of the tomato and human orthologs of DET1. In order to reveal the mechanism and molecular context of DET1 action, suppressor mutant screens were employed to discover additional genes acting in conjunction with DET1 (designated as TED genes). In this research, new genomic methods were developed and employed to identify the genes underlying the ted1-1SD and ted2-1D suppressor mutations. A long hypocotyl QTL and suppression of the det1-1 dark grown phenotype by the Bensheim (Be-0) ecotype of Arabidopsis mapped to the HAT4 gene, a homeoboxdomain leucine-zipper transcription factor involved in shade-avoidance responses. Sequence analysis uncovered two functionally distinct alleles of HAT4 in the Be-0 alleles of HAT4 compared to the genomic standard Columbia (Col-0) ecotype. Expression analysis showed that in addition to negative autoregulation by itself, HAT4 is also negatively regulated by DET1. The ted2-1D mutation was mapped to a 57 Kbp interval on chromosome I containing three likely candidate genes. Suppression of the det1-1 phenotype by ted2-1D is overdominant which is highly unusual and typically associated with hybrid vigor or heterosis traits. The discovery of the genes underlying the ted1-1SD and ted2-1D suppressor mutations have furthered the understanding of the role for DET1 in regulation of photomorphogenesis as well as mechanisms involved in overall gene regulation during light signaling.

Arabidopsis

photomorphogenesis

hypocotyl

light signaling

Light regulation and functional characterization of Phytochrome Interacting Factor 1 (PIF1) in Arabidopsis

Zhu, Ling

17 July 2012

Plants sense light intensity, quality and direction through a group of photoreceptors to modulate their growth and development. One family of photoreceptor is called phytochromes (phys) that perceives red and far red light. Phys transduce light signals via a sub-family of the basic Helix-Loop-Helix (bHLH) transcription factors called Phytochrome Interacting Factors (PIFs). PIFs function as negative regulators in the phy-mediated light signaling pathways. In darkness, PIFs regulate downstream gene expressions to inhibit photomorphogenesis. Upon light exposure, PIFs are phosphorylated and poly-ubiquitylated prior to their rapid degradation through the 26S proteasome pathway. One of the PIFs, PIF1, has the highest affinity for both phyA and phyB and also displayed the fastest degradation kinetics under both red and far red light. Here we showed that PIF1 directly and indirectly regulates key genes involved in chlorophyll biosynthesis to optimize the greening process in Arabidopsis. PIF1 binds to a G-box (CACGTG) DNA sequence element present in its direct target genes (e.g., protochlorophyllide oxidoreductase C, PORC) in darkness and regulates their expression. Structure-function studies revealed two separate regions called APB and APA necessary for binding to phyB and phyA, respectively, located at the amino-terminus and a novel phosphorylation site at the carboxy-terminus of PIF1. Both amino- and carboxy-terminal regions are necessary for the light-induced degradation of PIF1. However, the DNA binding is not necessary for the light-induced degradation of PIF1. Using a targeted systems biology approach, we identified new factors, HECATE proteins that promote photomorphogenesis by negatively regulating the function of PIF1. Moreover, we employed an unbiased genetic screening using luciferase imaging system to identify new mutants defective in the light-induced degradation of PIF1. The cloning and characterization of these mutants will help identify the factors, such as the kinase and E3 ligase, responsible for the light-induced degradation of PIF1. Taken together, these data revealed detail mechanisms of how PIF1 negatively regulates photomorphogenesis and how light induces rapid degradation of PIF1 to promote photomorphogenesis. / text

Photomorphogenesis

Phytochromes

PIFs

Phytochrome and phytohormone interplay in tomato: impacts on fruit physiology and quality traits / Interações entre fitocromos e fitormônios em tomateiro: impactos na fisiologia e qualidade nutricional dos frutos

Bianchetti, Ricardo Ernesto

12 December 2017

Phytochromes (PHYs) and plant hormones have been emerging as important regulators of fleshy fruit physiology and quality traits; however, the relevance of PHY-hormonal signaling crosstalk in controlling fruit development and metabolism remains elusive. This Thesis assesses the role of PHYs and their interplay with auxins, cytokinins and ethylene during the regulation of tomato (Solanum lycopersicum) fruit development and ripening, with a focus on the control of the plastid biogenesis, sugar metabolism and carotenoid accumulation. In Chapter I, we present evidence that the deficiency in PHY chromophore phytochromobilin (PΦB) biosynthesis, which leads to a global deficiency in functional PHYs, represses fruit chloroplast biogenesis in immature fruits and inhibits fruit sugar accumulation by transcriptionally downregulating sink- and starch biosynthesis-related enzymes. Genetic and physiological evidence suggested the involvement of both auxins and cytokinins as mediators of the negative impact of PΦB deficiency on fruit sink strength and chloroplast formation. During the ripening phase, PΦB deficiency was shown to delay the rise in climacteric ethylene production, affecting the ripening initiation rather than its progression. PHY-hormonal signaling crosstalk was shown to be active not only in the more externally positioned fruit tissues (i.e., pericarp) but also in the most inner fruit regions (i.e., columella). We, therefore, concluded that the global deficiency in functional PHY drastically affects fruit sugar metabolism, chloroplast formation as well as the timing of ripening via an intricate interplay involving phytochromes, auxins, cytokinins and ethylene. In Chapter II, we employed fruit-specific RNAi-mediated silencing of PHY genes to shed light on the specific role played by fruit-localized PHYs and their downstream signaling cascades on tomato fruit physiology and quality traits. Data revealed that fruit-localized SlPHYB2 negatively regulates chlorophyll accumulation in immature fruits whereas SlPHYA positively influences the plastid division machinery. Both SlPHYA and SlPHYB2 were shown to play overlapping, yet distinct, roles in controlling fruit starch metabolism and carotenoid biosynthesis. Our data implicated cytokinin signaling-related proteins as mediators of the SlPHYA-dependent regulation of plastid division machinery, and specific AUXIN RESPONSE FACTORs as intermediates in the PHY-mediated regulation of fruit sugar and carotenoid metabolisms. We concluded that fruit-localized SlPHYA- and SlPHYB2-mediated light perception regulate fruit plastid biogenesis as well as sugar and carotenoid metabolisms via coordinated changes in key components of both auxin and cytokinin signaling cascades. Altogether, this study brings important insights into the combined action of PHYs and hormones in the control of fruit plastid biogenesis and highlights that the interplay between PHY-hormonal signaling cascades influences essential features of tomato fruit quality, such as the sugar and carotenoid accumulation / Fitocromos (PHYs) e fitormônios têm sido caracterizados como importantes reguladores da fisiologia e qualidade de frutos carnosos; todavia, a importância de interações entre a sinalização hormonal e dos PHYs no controle do desenvolvimento e metabolismo de frutos ainda permanece pouco elucidada. Este trabalho de Tese avaliou o papel dos PHYs e das suas interações com as auxinas, as citocininas e o etileno sobre a regulação do desenvolvimento e amadurecimento de frutos de tomateiro (Solanum lycopersicum), particularmente no que tange ao controle da biogênese plastidial e metabolismos de açúcares e de carotenoides. No Capítulo I são apresentadas evidências de que a deficiência na produção de fitocromobilina (PΦB), a qual resulta numa deficiência global in PHYs funcionais, impacta negativamente a biogênese de cloroplastos em frutos imaturos e inibe o acúmulo de açúcares por meio da repressão transcricional de enzimas relacionadas a biossíntese de amido e força de dreno nos frutos. Evidências genéticas e fisiológicas indicaram o envolvimento tanto das auxinas quanto das citocininas como mediadoras do impacto negativo da deficiência de PΦB sobre a força de dreno dos frutos bem como na formação de cloroplastos. Durante a fase de amadurecimento, a deficiência em PΦB atrasou a produção climatérica de etileno, afetando o início do amadurecimento mas não a sua progressão. As interações entre PHYs e hormônios mostraram-se ativas não apenas nos tecidos posicionados mais externamente (i.e., pericarpo) mas também nas regiões mais internas do fruto (i.e., columela). Conclui-se, portanto, que a deficiência global em PHYs funcionais afeta drasticamente o metabolismo de açucares, formação de cloroplastos, bem como o tempo de amadurecimento através de uma interação complexa envolvendo fitocromos, auxinas, citocininas e etileno. No Capítulo II utilizamos o silenciamento fruto-específico de PHYs a fim de desvendar de que forma a fisiologia e parâmetros de qualidade do tomate seriam regulados por PHYs presentes no próprio fruto. Os dados obtidos revelaram que moléculas de SlPHYB2 presentes no próprio fruto regulam negativamente o acúmulo de clorofilas nos frutos imaturos, já as de SlPHYA influenciam positivamente a maquinaria de divisão plastidial, e tanto SlPHYA quanto SlPHYB2 desempenham papel sobrepostos, porém distintos, no controle do metabolismo de amido e acúmulo de carotenoides em frutos de tomateiro. Evidências sugerem que proteínas relacionadas à sinalização de citocininas atuariam como mediadoras do impacto de SlPHYA sobre a maquinaria de divisão plastidial, e que AUXIN RESPONSE FACTORs específicos seriam intermediários no controle dos PHYs sobre os metabolismos de açúcares e carotenoides. Conclui-se, dessa forma, que a percepção de luz mediada por moléculas de SlPHYA e SlPHYB2 presentes no próprio fruto regulam a biogênese plastidial e os metabolismos de açúcares e carotenoides por meio de alterações coordenadas em componentes chaves das cascatas de sinalização de auxinas e citocininas. Quando combinados, os dados obtidos neste estudo apresentam novidades importantes sobre a ação conjunta de PHYs e fitormônios no controle da biogênese plastidial e demonstram que a interação entre esses sinalizadores influencia características essenciais da qualidade de frutos de tomateiro, tais como o acúmulo de açúcares e de carotenoides

Amido

Auxin

Auxina

Chloroplast

Citocinina

Cloroplasto

Cytokinin

Light signaling

Sinalização luminosa

Starch

Phytochrome and phytohormone interplay in tomato: impacts on fruit physiology and quality traits / Interações entre fitocromos e fitormônios em tomateiro: impactos na fisiologia e qualidade nutricional dos frutos

Ricardo Ernesto Bianchetti

12 December 2017

Phytochromes (PHYs) and plant hormones have been emerging as important regulators of fleshy fruit physiology and quality traits; however, the relevance of PHY-hormonal signaling crosstalk in controlling fruit development and metabolism remains elusive. This Thesis assesses the role of PHYs and their interplay with auxins, cytokinins and ethylene during the regulation of tomato (Solanum lycopersicum) fruit development and ripening, with a focus on the control of the plastid biogenesis, sugar metabolism and carotenoid accumulation. In Chapter I, we present evidence that the deficiency in PHY chromophore phytochromobilin (PΦB) biosynthesis, which leads to a global deficiency in functional PHYs, represses fruit chloroplast biogenesis in immature fruits and inhibits fruit sugar accumulation by transcriptionally downregulating sink- and starch biosynthesis-related enzymes. Genetic and physiological evidence suggested the involvement of both auxins and cytokinins as mediators of the negative impact of PΦB deficiency on fruit sink strength and chloroplast formation. During the ripening phase, PΦB deficiency was shown to delay the rise in climacteric ethylene production, affecting the ripening initiation rather than its progression. PHY-hormonal signaling crosstalk was shown to be active not only in the more externally positioned fruit tissues (i.e., pericarp) but also in the most inner fruit regions (i.e., columella). We, therefore, concluded that the global deficiency in functional PHY drastically affects fruit sugar metabolism, chloroplast formation as well as the timing of ripening via an intricate interplay involving phytochromes, auxins, cytokinins and ethylene. In Chapter II, we employed fruit-specific RNAi-mediated silencing of PHY genes to shed light on the specific role played by fruit-localized PHYs and their downstream signaling cascades on tomato fruit physiology and quality traits. Data revealed that fruit-localized SlPHYB2 negatively regulates chlorophyll accumulation in immature fruits whereas SlPHYA positively influences the plastid division machinery. Both SlPHYA and SlPHYB2 were shown to play overlapping, yet distinct, roles in controlling fruit starch metabolism and carotenoid biosynthesis. Our data implicated cytokinin signaling-related proteins as mediators of the SlPHYA-dependent regulation of plastid division machinery, and specific AUXIN RESPONSE FACTORs as intermediates in the PHY-mediated regulation of fruit sugar and carotenoid metabolisms. We concluded that fruit-localized SlPHYA- and SlPHYB2-mediated light perception regulate fruit plastid biogenesis as well as sugar and carotenoid metabolisms via coordinated changes in key components of both auxin and cytokinin signaling cascades. Altogether, this study brings important insights into the combined action of PHYs and hormones in the control of fruit plastid biogenesis and highlights that the interplay between PHY-hormonal signaling cascades influences essential features of tomato fruit quality, such as the sugar and carotenoid accumulation / Fitocromos (PHYs) e fitormônios têm sido caracterizados como importantes reguladores da fisiologia e qualidade de frutos carnosos; todavia, a importância de interações entre a sinalização hormonal e dos PHYs no controle do desenvolvimento e metabolismo de frutos ainda permanece pouco elucidada. Este trabalho de Tese avaliou o papel dos PHYs e das suas interações com as auxinas, as citocininas e o etileno sobre a regulação do desenvolvimento e amadurecimento de frutos de tomateiro (Solanum lycopersicum), particularmente no que tange ao controle da biogênese plastidial e metabolismos de açúcares e de carotenoides. No Capítulo I são apresentadas evidências de que a deficiência na produção de fitocromobilina (PΦB), a qual resulta numa deficiência global in PHYs funcionais, impacta negativamente a biogênese de cloroplastos em frutos imaturos e inibe o acúmulo de açúcares por meio da repressão transcricional de enzimas relacionadas a biossíntese de amido e força de dreno nos frutos. Evidências genéticas e fisiológicas indicaram o envolvimento tanto das auxinas quanto das citocininas como mediadoras do impacto negativo da deficiência de PΦB sobre a força de dreno dos frutos bem como na formação de cloroplastos. Durante a fase de amadurecimento, a deficiência em PΦB atrasou a produção climatérica de etileno, afetando o início do amadurecimento mas não a sua progressão. As interações entre PHYs e hormônios mostraram-se ativas não apenas nos tecidos posicionados mais externamente (i.e., pericarpo) mas também nas regiões mais internas do fruto (i.e., columela). Conclui-se, portanto, que a deficiência global em PHYs funcionais afeta drasticamente o metabolismo de açucares, formação de cloroplastos, bem como o tempo de amadurecimento através de uma interação complexa envolvendo fitocromos, auxinas, citocininas e etileno. No Capítulo II utilizamos o silenciamento fruto-específico de PHYs a fim de desvendar de que forma a fisiologia e parâmetros de qualidade do tomate seriam regulados por PHYs presentes no próprio fruto. Os dados obtidos revelaram que moléculas de SlPHYB2 presentes no próprio fruto regulam negativamente o acúmulo de clorofilas nos frutos imaturos, já as de SlPHYA influenciam positivamente a maquinaria de divisão plastidial, e tanto SlPHYA quanto SlPHYB2 desempenham papel sobrepostos, porém distintos, no controle do metabolismo de amido e acúmulo de carotenoides em frutos de tomateiro. Evidências sugerem que proteínas relacionadas à sinalização de citocininas atuariam como mediadoras do impacto de SlPHYA sobre a maquinaria de divisão plastidial, e que AUXIN RESPONSE FACTORs específicos seriam intermediários no controle dos PHYs sobre os metabolismos de açúcares e carotenoides. Conclui-se, dessa forma, que a percepção de luz mediada por moléculas de SlPHYA e SlPHYB2 presentes no próprio fruto regulam a biogênese plastidial e os metabolismos de açúcares e carotenoides por meio de alterações coordenadas em componentes chaves das cascatas de sinalização de auxinas e citocininas. Quando combinados, os dados obtidos neste estudo apresentam novidades importantes sobre a ação conjunta de PHYs e fitormônios no controle da biogênese plastidial e demonstram que a interação entre esses sinalizadores influencia características essenciais da qualidade de frutos de tomateiro, tais como o acúmulo de açúcares e de carotenoides

Amido

Auxina

Citocinina

Cloroplasto

Sinalização luminosa

Auxin

Chloroplast

Cytokinin

Light signaling

Starch