Elucidating three novel mechanisms of Pseudomonas syringae pathogenicity

Clarke, Christopher R.

12 March 2012

Pseudomonas syringae is an important bacterial plant pathogen that, as a species, is known to cause disease on hundreds of different plant species. However, any individual pathovar of P. syringae typically only causes disease on one or a few plant species, which constitute the host range of the pathovar. Plants are generally resistant to most pathogens primarily because the plant innate immune system is capable of recognizing conserved microbial-associated molecular patterns (MAMPs). Adapted pathovars of P. syringae secrete effector proteins through a Type Three Secretion System (T3SS) to suppress the immune response elicited by their MAMPs. However, secretion of effectors can also trigger a strong plant immune response if the plant harbors resistance proteins capable of recognizing the secreted effectors. Successful pathovars, therefore, must secrete a combination of effectors capable of suppressing MAMP/Pattern-Triggered Immunity (PTI) without eliciting Effector-Triggered Immunity. Here we identify several novel strategies employed by P. syringae to overcome the plant immune system and cause disease. First, we demonstrate that, in place of the canonical T3SS used by all known pathogens of P. syringae, several apparently nonpathogenic isolates of P. syringae employ a novel T3SS that is functional but not necessary for colonization of plants. Despite being closely related to pathogenic isolates of P. syringae, the isolates employing the noncanonical T3SS do not cause disease on any tested plants and instead appear to act more as commensal organisms. Second, we advance the understanding of PTI by identifying a second region of bacterial flagellin that triggers PTI in addition to the archetypical MAMP flg22, which is recognized by the archetypical plant receptor FLS2. This new elicitor, termed flgII-28, is also detected by FLS2 and appears to be under selection in very closely related lineages of P. syringae. Alleles of flagellin present in one recently expanded and agriculturally problematic lineage of P. syringae appear to trigger less PTI on their host plant, tomato, than the ancestral allele suggesting that avoidance of PTI through allelic diversity in MAMPs is an effective alternative strategy to suppression of PTI through delivery of effectors. Finally, we start to elucidate a role for chemotaxis (chemical-directed movement) in P. syringae pathogenicity. Not only is chemotaxis required for pathogenicity of P. syringae on plants, but it also appears to contribute to delimiting the host range of several P. syringae pathovars. These results highlight that additional aspects of P. syringae pathogenicity, such as chemotaxis, can directly contribute to defining the host range of individual P. syringae pathovars. The current paradigm of P. syringae pathogenicity posits that MAMPS and the repertoire of effector proteins are the primary determinant of the host range of any P. syringae pathovar; in contrast these results inspire a more nuanced view of pathogenicity that considers multiple aspects of the infection process. / Ph. D.

Molecular plant-microbe interactions

plant immunity

plant pathology

Pseudomonas syringae

chemotaxis

MAMPs

PAMPS

Microbial endophytes and their interactions with cranberry plants

Bustamante Villalobos, Peniel

01 1900

Virtuellement toutes les plantes hébergent des champignons et des bactéries endosymbiontes (endophytes). Ces microorganismes façonnent le développement de leur hôte et peuvent inhiber des phytopathogènes. Au niveau moléculaire, les interactions plante-endophyte sont médiées par des molécules secrétées y compris des protéines et métabolites secondaires. Au cours des dernières années, la recherche d’endophytes a augmenté chez nombreux plantes, cependant chez les Ericaceae les endophytes ne sont pas bien connus. Alors, on s’est mis à investiguer les endophytes racinaires de la canneberge, une plante membre d’Ericaceae native de l’Amérique du Nord. On a échantillonné quatre plants provenant d’une ferme commerciale organique. Au total, 30 souches fongiques et 25 bactériens ont été isolés. Les bactéries Pseudomonas sp. EB212, Bacillus sp. EB213 et EB214; et les champignons Hyaloscypha sp. EC200, Pezicula sp. EC205 et Phialocephala sp. EC208 ont supprimé la croissance de cinq pathogènes de la canneberge, incluant Godronia cassandrae, un champignon causant la pourriture des fruits de la canneberge au Québec. EB213 a été capable de promouvoir légèrement la croissance de plantules de la canneberge. En performant des techniques microscopiques, on a constaté l’habileté de EC200, EC205 et EC208 à coloniser internement les racines des plantules de la canneberge. De plus, les génomes de ces champignons ont été séquencés, assemblés et annotés. Les analyses génomiques se sont concentrées sur les protéines secrétées et les groupes des gènes impliqués dans la biosynthèse (GGB). On a trouvé un large répertoire de gènes codant pour des enzymes qui métabolisent les carbohydrates et d’autres codant pour des protéases. Les deux groupes d’enzymes seraient utiles à dégrader de la matière organique pour libérer des nutriments. Aussi bien, ces enzymes pourraient faciliter la colonisation des racines de la plante hôte. De plus, on a prédit des nombreuses protéines effectrices qui assisteraient les endophytes à éviter l’activation du système immunitaire des plants. A noter que parmi les GGB inférés dans les génomes de EC200, EC205 et EC208, environ 90% ne sont pas caractérisés. Finalement, on a performé des analyses transcriptomiques pour élucider la réponse de EC200, EC205 et EC208 envers la présence de leur hôte, simulée par l’addition d’un extrait de canneberge au milieu de culture. Les conclusions majeures sont que les racines des plantes de la canneberge qui ont été échantillonnées sont dominées par des microorganismes avec l’habileté d’inhiber des phytopathogènes ; et que les génomes de EC200, EC205 et EC208 codent pour un grand répertoire de protéines qui pourraient être liées aux interactions plante-endophyte. / Virtually all plants host fungal and bacterial endosymbionts (endophytes). These microbes shape plant development and may inhibit phytopathogens. At the molecular level, plant-endophyte interactions are mediated by secreted compounds, including proteins and secondary metabolites. While endophytes are increasingly studied in diverse plants, little is known about their presence in Ericaceae. Therefore, we set out to investigate the root endophytes of cranberry, an ericacean member native to North America. We sampled endophytes from four plants grown on an organic farm. In total, 30 fungal and 25 bacterial strains were isolated and identified. A subset of these, notably Pseudomonas sp. EB212, Bacillus sp. EB213 and EB214; and fungi Hyaloscypha sp. EC200, Pezicula sp. EC205, and Phialocephala sp. EC208, were tested for their ability to suppress phytopathogens. Altogether, they inhibited five cranberry pathogens, including Godronia cassandrae, an important cranberry fruit-rot agent in Quebec. EB213 was the only endophyte that increased the biomass of cranberry seedlings. Using microscopy techniques, we confirmed the ability of EC200, EC205, and EC208 to colonize cranberry roots internally. The genomes of these fungi were sequenced, assembled and annotated. Genomic analyses focused on secreted proteins and biosynthetic gene clusters (BGCs). We found an extensive repertoire of carbohydrate-active enzymes and proteases that could assist in recycling organic nutrients, rendering them accessible to plants; these enzymes may also facilitate root colonization. In addition, effector proteins were predicted; these molecules may assist endophytes to escape the plant immune system and favour colonization. We inferred 139 biosynthetic gene clusters (BGCs) across the three examined fungi. Remarkably, the product of around 90% of BGCs are unknown. Finally, transcriptomic analyses were performed to determine how EC200, EC205 and EC208 respond to the presence of cranberry, simulated by the addition of cranberry extract in the culture medium. The two major conclusions of this work are that the roots of the sampled cranberry plants are dominated by endophytes with biocontrol abilities, and that EC200, EC205 and EC208 encode a broad repertoire of proteins that could be involved in plant-endophyte interactions.

Endophytes de la canneberge

Interactions plant-microbe

Biocontrôle

promotion de la croissance des plantes

Microscopie

Génomique comparative

Transcriptomique comparative

Sécrétome

Effectome

Métabolites secondaires

Cranberry endophytes

Plant-microbe interactions

Biocontrol

Plant growth-promotion

Microscopy

Comparative genomics

Comparative transcriptomics

Secondary metabolites

Interação entre bactérias endofíticas e do rizoplano com Eucalyptus / Interaction between endophytic and rhizoplane bacteria with Eucalyptus

Ferreira, Anderson

15 February 2008

Os microrganismos endofíticos são aqueles, cultiváveis ou não, que habitam o interior da planta hospedeira sem causar danos aparentes ou estruturas externas visíveis. Essa interação microrganismos-planta é intrínseca a determinadas espécies de plantas e/ou bactérias. Nas últimas décadas os estudos de microrganismos endofíticos têm sido realizados em diversas plantas hospedeiras, sendo esses estudos direcionados principalmente para a diversidade e características benéficas induzidas, inclusive o controle biológico de doenças. A doença causada pelo fungo Ceratocystis fimbriata é considerada emergente no setor florestal. O Brasil está entre os maiores produtores mundiais de eucalipto e a expansão do setor juntamente com o cultivo clonal tem acarretado o aumento da incidência de patógenos. O surgimento de novas doenças exige estudos relacionados tanto a interação do agente patogênico com hospedeiro quanto de todos os componentes do patossistema. Neste contexto, os microrganismos endofíticos têm sido descritos como potenciais controladores biológicos de doenças. Dessa forma, o presente trabalho teve por objetivos avaliar a interação de C. fimbriata com a comunidade bacteriana associada à Eucalyptus sp. Adicionalmente, foi estudada a possível transferência desses endófitos via sementes e o padrão de colonização de Pantoea agglomerans em plântulas. Foi observado que plantas não infestadas por C. fimbriata apresentaram maior densidade bacteriana no rizoplano (20,66 x 104 UFC.cm2 -1 de raiz), enquanto que para a comunidade endofítica, a maior densidade foi observada em plantas infectadas pelo fungo (25,13 x 104 UFC.g-1 de raiz). As análises por ARDRA possibilitaram a obtenção de 8 e 13 ribotipos nas comunidades endofítica de raiz e do rizoplano, respectivamente. Os ribotipos mais freqüentes foram identificados como Bacillus cereus. As análises de diversidade por meio de DGGE das comunidades do rizoplano e endofítica de raiz mostraram que a infestação pelo fungo interfere na colonização de Eucalyptus. Foi observado também que bactérias endofíticas estão presentes no interior de sementes de Eucalyptus spp. em uma densidade de 0,33 a 1,83 X 102 UFC.g-1, para as espécies E. camandulensis e E. urophylla, respectivamente. A densidade bacteriana endofítica de plântulas obtidas de sementes desinfectadas superficialmente variaram entre 0,27 X 102 a 0,87 X 102 UFC.g-1, para E. citriodora e o híbrido E. robusta x E. grandis, respectivamente. Em algumas espécies de Eucalyptus não foram isoladas bactérias endofíticas das sementes e plântulas. Os resultados mostraram que algumas espécies de bactérias endofíticas podem ser transmitidas verticalmente por sementes. P. agglomerans inoculada nas sementes foi capaz de colonizar as plântulas após a germinação da semente, indicando que esta pode ser uma das formas utilizadas pelos microrganismos para colonizar e se estabelecer na planta hospedeira. Assim, os resultados obtidos neste trabalho mostram ainda que possa existir interação entre a presença de C. fimbriata e a comunidade bacteriana endofítica e do rizoplano de Eucalyptus. Foi possível observar também que estas bactérias endofíticas que são transmitidas por meio de sementes, permitindo que plântulas previamente inoculadas com bactérias benéficas possam ser produzidas antes de serem levadas a campo. / The endophytic microorganisms are those, cultivated or not, that inhabit the interior of the plant host without causing apparent damages or visible external structures. This interaction microorganisms-plant is specific to certain species of plants and/or bacteria. In the last few years studies of endophytic microorganisms have been carried out in several plant hosts, being these studies focused mainly to diversity and biotechnological potential, such as biological control of disease. The disease caused by the phytopathogenic fungi Ceratocystis fimbriata is considered emerging by the reforestation companies. Brazil is one of the largest world eucalyptus producers and the increasing of the eucalyptus production associated to clonal reproduction has allowed the increase in pathogen incidence. Studies that evaluate the interaction between pathogens and the microbial community associated to the host plant may allow understanding how disease symptoms come up. Endophytic microorganisms have been described as potential biological control of diseases and therefore, the aims of the present work were to i) study the interaction between C. fimbriata and the bacterial community associated to the Eucalyptus sp.; ii) evaluate the bacterial dissemination by seeds; iii) evaluate the colonization profile of Pantoea agglomerans in seedlings after seed inoculation. It was observed that the highest bacterial density on the rhizoplane (20.66 x 104 CFU.cm2 -1 of root) was observed in C. fimbriata uninfectedplants, while for endophytic community the highest density was observed in C. fimbriata infected plants (25.13 x 104 CFU.g-1 of root). The ARDRA analyses showed that the bacterial community of eucalyptus is composed by 8 and 13 ribotypes on rhizoplane and inside the roots (endophytic), respectively. The most frequent ribotypes were identified as Bacillus cereus. The DGGE analyses of diversity of endophytic and rhizoplane community showed that fungi infection shift the colonization of Eucalyptus associated bacteria. The bacterial community inside Eucalyptus spp. seeds ranged from 0.33 to 1.83 X 102 CFU.g-1, for E. camandulensis and E. urophylla, respectively. After seed germination the endophytic bacterial density in seedlings ranged from 0,27 X 102 to 0,87 X 102 CFU.g-1, for E. citriodora and the hybrid E. robusta x E. grandis, respectively. Although, endophytic bacteria have been isolated from seeds, for some plant species, bacteria were not isolated from seedlings. Also, some bacteria may be vertically transmitted from seed to seedlings, but some is specific for seeds. Seed inoculation of P. agglomerans resulted in seedlings colonized by these bacteria, suggesting that these bacteria could be seed transmitted. The results obtained in the present study show that the fungi C. fimbriata inside the Eucalyptus host can shift the endophytic and rhizoplane bacterial diversity. Also, these endophytic bacteria could be transmitted vertically by seeds, allowing that seeds previously inoculated with beneficial bacteria may result in protected plants before planting in the field.

16S rDNA

Bactérias

DGGE

Ecologia microbiana

Eucalipto

Fluorescence microscopy.

Fungos fitopatogênicos

Microbial ecology

Microrganismos endofíticos.

Plant microbe interctions

Identification of genes and proteins involved in the regulation of orchid mycorrhiza / Identificação de genes e proteínas envolvidos na regulação de micorrizas de orquídeas

Rafael Borges da Silva Valadares

14 February 2014

Orchids are characterized by producing minute endosperm-lacking seeds, which depend on mycorrhizal fungi for germination and embryo development. Some aclorophyllous orchids remain dependent on the mycorrhizal association for carbon acquisition during their whole life history, whereasother orchids develop photosynthesis. Despite the biological significance of orchid mycorrhiza, gene expression studies are lacking. We have used different highthroughput approaches in order to understanding the mechanisms regulating orchid mycorrhiza development and functioning. Firstly, we have used a 2D-LC-MS/MS approach coupled to isobaric tagging for relative and absolute quantification (iTRAQ) to identify proteins with differential accumulation in Oncidium sphacelatum at different stages of mycorrhizal protocorm development (achlorophyllous and green protocorms) after seed inoculation with a Ceratobasidium sp. isolate. Quantitative analysis showed that the expected changes in carbon metabolism in green protocorms were accompanied by enhanced accumulation of proteins involved in the modulation of reactive oxygen species homeostasis, defense related responses, phytoalexins and carotenoid biosynthesis, suggesting that orchid protocorms undergo profound metabolic changes during the switch from the fully mycoheterotrophic to the photosynthethic stage. Secondly, three different proteomic techniques were carried out in independent experiments aiming to identify changes in protein accumulation in mycorrhizal roots of the terrestrial orchid Oeceoclades maculata.Finally, O. maculatamycorrhizal roots were used for transcriptome analyses. The data revealed a strong increase in general stress responses, accompanied by changes in signaling pathways possibly related to fungal recognition and establishment of a compatible interaction. Some of the upregulated genes may be involved in the reorganization of cell structure, likely related to accommodation of the fungal symbiont in the plant roots. We have also observed in mycorrhizal roots up-regulation of genes involved in carbon metabolism, including glycolysis/gluconeogenesis and amino sugars metabolism, as well as genes involved innitrogen assimilation. The down-regulation of genes involved in the jasmonate and ABA transduction pathways, and key genes encoding anti-fungal proteins, such as chitinase and a mannose-specific binding lectin, strongly suggests an alleviation of plant defense responses in O. maculata mycorrhizal roots. In general, our data suggest that the physiology of an orchid mycorrhiza is more similar to a compatible interaction than to an arm-race between plant and fungi. Overall orchid mycorrhiza have proved to be a promising model for investigating plantfungal interactions and further studies should now address the specific roles of the genes showing differential regulation in this study. / As orquídeas são caracterizadas por produzirem sementes diminutas, que não possuem endosperma. Necessitam, portanto, da interação com fungos micorrízicos para germinação e desenvolvimento do embrião. Algumas orquídeas aclorofiladas se mantêm dependentes dos fungos micorrízicos para a aquisição de carbono, enquanto outras desenvolvem a maquinaria fotossintética. Apesar do significado biológico das micorrizas de orquídeas, alterações na expressão gênica e no acúmulo de proteínas foram altamente negligenciads nos últimos anos. Neste trabalho, foram utilizadas diferentes técnicas sequenciamento e identificação de genes e proteínas em larga-escala para acessar as alterações moleculares responsáveis pela regulação das micorrizas de orquídeas. Uma abordagem baseada em 2D-LC MS/MS acoplada a técnica de quantificação absoluta e relativa iTRAQ, foiutilizada para identificar proteínas com acúmulo diferencial em Oncidium sphacelatum em diferentes estágios do desenvolvimento do protocormo (protocormos aclorofilados versus protocormos fotossintetizantes), após inoculação com um fungo do gênero Ceratobasidium. As análises mostraram que, as alterações esperadas no metabolismo do carbono foram acompanhadas de um acúmulo aumentado de proteínas envolvidas na modulação de espécies reativas de oxigênio, respostas de defesa, biossíntese de fitoalexinas e carotenóides, sugerindo que os protocormos de orquídeas passam por profundas alterações metabolicas durante a transição do metabolismo micoheterotrófico para o fotossintético. Posteriormente foram utilizadas três diferentes técnicas de proteômica quantitativa para explorar alterações fisiológicas em raízes micorrizadas e não-micorrizadas de Oeceoclades maculata.Este estudo foi ampliado, pela utilização de uma abordagem transcritômica ao mesmo modelo biológico. Em conjunto, os dados revelaram um forte aumento em respostas relacionadas ao estresse, acompanhadas de alterações em vias de transdução de sinal possivelmente relacionadas ao reconhecimento do simbionte fúngico e estabelecimento de uma interação compatível. Alguns genes com expressão aumentada devem estar envolvidos na reorganização celular, provavelmente ligada a acomodação do simbionte fúngico nas raízes das plantas. Também foi observado o aumento de genes envolvidos no metabolismo do carbono e de açúcares aminados, juntamente a genes relacionados a assimilação de nitrogênio em raízes micorrizadas. A expressão diminuída de genes envolvidas nas vias do jasmonato e ácido abscícico, juntamente a genes-chave que codificam para proteínas anti-fúngicas sugerem fortemente uma atenuação das respostas de defesa da planta em raízes micorrizadas de Oeceoclades maculata. No geral, parece que as micorrizas de orquídeas são fisiológicamente mais próximas de uma simbiose compatível do que de uma interação unilateral em favor da planta. Sobretudo, este sistema biológico provou ser promissor para investigação de interações planta-fungo e, próximas pesquisas devem agora ser focadas em funções específicas dos genes que mostraram regulação diferencial neste estudo.

Genes de defesa vegetal

Interação-planta-micro-organismo

Proteômica

Simbiose

Transcritômica

Plant defense genes

Plant-microbe interaction

Proteomics

Symbiosis

Transcriptomics

Identification of genes and proteins involved in the regulation of orchid mycorrhiza / Identificação de genes e proteínas envolvidos na regulação de micorrizas de orquídeas

Valadares, Rafael Borges da Silva

14 February 2014

Orchids are characterized by producing minute endosperm-lacking seeds, which depend on mycorrhizal fungi for germination and embryo development. Some aclorophyllous orchids remain dependent on the mycorrhizal association for carbon acquisition during their whole life history, whereasother orchids develop photosynthesis. Despite the biological significance of orchid mycorrhiza, gene expression studies are lacking. We have used different highthroughput approaches in order to understanding the mechanisms regulating orchid mycorrhiza development and functioning. Firstly, we have used a 2D-LC-MS/MS approach coupled to isobaric tagging for relative and absolute quantification (iTRAQ) to identify proteins with differential accumulation in Oncidium sphacelatum at different stages of mycorrhizal protocorm development (achlorophyllous and green protocorms) after seed inoculation with a Ceratobasidium sp. isolate. Quantitative analysis showed that the expected changes in carbon metabolism in green protocorms were accompanied by enhanced accumulation of proteins involved in the modulation of reactive oxygen species homeostasis, defense related responses, phytoalexins and carotenoid biosynthesis, suggesting that orchid protocorms undergo profound metabolic changes during the switch from the fully mycoheterotrophic to the photosynthethic stage. Secondly, three different proteomic techniques were carried out in independent experiments aiming to identify changes in protein accumulation in mycorrhizal roots of the terrestrial orchid Oeceoclades maculata.Finally, O. maculatamycorrhizal roots were used for transcriptome analyses. The data revealed a strong increase in general stress responses, accompanied by changes in signaling pathways possibly related to fungal recognition and establishment of a compatible interaction. Some of the upregulated genes may be involved in the reorganization of cell structure, likely related to accommodation of the fungal symbiont in the plant roots. We have also observed in mycorrhizal roots up-regulation of genes involved in carbon metabolism, including glycolysis/gluconeogenesis and amino sugars metabolism, as well as genes involved innitrogen assimilation. The down-regulation of genes involved in the jasmonate and ABA transduction pathways, and key genes encoding anti-fungal proteins, such as chitinase and a mannose-specific binding lectin, strongly suggests an alleviation of plant defense responses in O. maculata mycorrhizal roots. In general, our data suggest that the physiology of an orchid mycorrhiza is more similar to a compatible interaction than to an arm-race between plant and fungi. Overall orchid mycorrhiza have proved to be a promising model for investigating plantfungal interactions and further studies should now address the specific roles of the genes showing differential regulation in this study. / As orquídeas são caracterizadas por produzirem sementes diminutas, que não possuem endosperma. Necessitam, portanto, da interação com fungos micorrízicos para germinação e desenvolvimento do embrião. Algumas orquídeas aclorofiladas se mantêm dependentes dos fungos micorrízicos para a aquisição de carbono, enquanto outras desenvolvem a maquinaria fotossintética. Apesar do significado biológico das micorrizas de orquídeas, alterações na expressão gênica e no acúmulo de proteínas foram altamente negligenciads nos últimos anos. Neste trabalho, foram utilizadas diferentes técnicas sequenciamento e identificação de genes e proteínas em larga-escala para acessar as alterações moleculares responsáveis pela regulação das micorrizas de orquídeas. Uma abordagem baseada em 2D-LC MS/MS acoplada a técnica de quantificação absoluta e relativa iTRAQ, foiutilizada para identificar proteínas com acúmulo diferencial em Oncidium sphacelatum em diferentes estágios do desenvolvimento do protocormo (protocormos aclorofilados versus protocormos fotossintetizantes), após inoculação com um fungo do gênero Ceratobasidium. As análises mostraram que, as alterações esperadas no metabolismo do carbono foram acompanhadas de um acúmulo aumentado de proteínas envolvidas na modulação de espécies reativas de oxigênio, respostas de defesa, biossíntese de fitoalexinas e carotenóides, sugerindo que os protocormos de orquídeas passam por profundas alterações metabolicas durante a transição do metabolismo micoheterotrófico para o fotossintético. Posteriormente foram utilizadas três diferentes técnicas de proteômica quantitativa para explorar alterações fisiológicas em raízes micorrizadas e não-micorrizadas de Oeceoclades maculata.Este estudo foi ampliado, pela utilização de uma abordagem transcritômica ao mesmo modelo biológico. Em conjunto, os dados revelaram um forte aumento em respostas relacionadas ao estresse, acompanhadas de alterações em vias de transdução de sinal possivelmente relacionadas ao reconhecimento do simbionte fúngico e estabelecimento de uma interação compatível. Alguns genes com expressão aumentada devem estar envolvidos na reorganização celular, provavelmente ligada a acomodação do simbionte fúngico nas raízes das plantas. Também foi observado o aumento de genes envolvidos no metabolismo do carbono e de açúcares aminados, juntamente a genes relacionados a assimilação de nitrogênio em raízes micorrizadas. A expressão diminuída de genes envolvidas nas vias do jasmonato e ácido abscícico, juntamente a genes-chave que codificam para proteínas anti-fúngicas sugerem fortemente uma atenuação das respostas de defesa da planta em raízes micorrizadas de Oeceoclades maculata. No geral, parece que as micorrizas de orquídeas são fisiológicamente mais próximas de uma simbiose compatível do que de uma interação unilateral em favor da planta. Sobretudo, este sistema biológico provou ser promissor para investigação de interações planta-fungo e, próximas pesquisas devem agora ser focadas em funções específicas dos genes que mostraram regulação diferencial neste estudo.

Genes de defesa vegetal

Interação-planta-micro-organismo

Plant defense genes

Plant-microbe interaction

Proteômica

Proteomics

Simbiose

Symbiosis

Transcriptomics

Transcritômica

Symbiosis with Nitrogen-fixing Rhizobia Influences Plant Defense Strategy and Plant-predator Interactions

Godschalx, Adrienne Louise

29 June 2017

As sessile organisms, plants evolved a plethora of defenses against their attackers. Given the role of plants as a primary food source for many organisms, plant defense has important implications for community ecology. Surprisingly, despite the potential to alter entire food webs and communities, the factors determining plant investment in defense are not well-understood, and are even less understood considering the numerous symbiotic interactions in the same plant. Legume-rhizobia symbioses engineer ecosystems by fixing nitrogen from the atmosphere in trade for plant photosynthates, yet connecting symbiotic resource exchange to food web interactions has yet to be established. Here I test how rhizobia influence plant defense and tritrophic interactions in lima bean (Fabaceae - Phaseolus lunatus L.): a model plant in chemical ecology research characterized by a broad range of different defenses. Examining suites of traits among lima bean genotypes, highly cyanogenic cultivars and wild type plants (high cyanotypes) produce more hook-shaped trichomes, as a putative combined approach of chemical and mechanical defenses, forming defense syndromes to protect against multiple feeding guilds (Chapter 2). Testing costs that may have contributed to forming tradeoffs among strategies, high cyanotypes show reduced fitness under plant-plant competition relative to low cyanotypes, but when challenged with herbivory, high cyanotypes fitness reductions are no longer evident (Chapter 3). Young leaves, not reproductive organs, are the most cyanogenic lima bean organ, and removal quantitatively decreases fitness, supporting assumptions that the most valuable tissues will be most highly defended (Chapter 4). Testing the degree to which nitrogen-fixing rhizobia contribute to cyanogenesis, high cyanotypes form more nodules than low cyanotypes. Quantitative relationships between nodule number and plant traits highlight the role symbiotic investment plays a role in plant defense and nutritive phenotype, while simultaneously, genotypically-determined levels of defense shape plant investment in symbiosis (Chapter 5). Interestingly, traits that trade off by cyanotype (i.e. high cyanogenesis but low indirect defense) reflect the patterns in plants with nitrogen-fixing rhizobia. Rhizobia-inoculated lima beans show reduced indirect defenses, recruiting fewer parasitoid wasps (Chapter 6) and predatory ants (Chapter 7). Examining plant-ant attraction in greater detail, ants prefer headspace regions above EFN droplets, corresponding with species-specific differences in suites of volatiles, indicating EFN, like floral nectar, can be scented to manipulate insect behavior (Chapter 8). Overall, understanding when investing in traits to recruit predators is more effective than investing in defensive chemistry, and how particular ecological contexts, such as symbioses can influence the outcome of defense allocation strategies remains a fascinating area of research. Determining the mechanisms underlying why rhizobia and other belowground microbial symbionts influence their host plants' above ground interactions, whether plants traits affected by symbiotic microbes are simply a function of the costs and benefits from resource exchange, or whether symbionts can influence the success of primarily direct versus indirectly defended plants is an important question for understanding complex trophic systems and connecting to agricultural implications for more effective biological pest control.

Plant defenses

Plant-microbe relationships

Symbiosis

Lima bean -- Diseases and pests

Legumes -- Diseases and pests

Rhizobium

Botanical chemistry

Biology

Plant Sciences

Rhizosphere-driven Lipopeptide Production by Different Strains of Bacillus spp. as Mechanism Involved in Biological Control of Plant Pathogens

Nihorimbere, Venant

04 February 2011

Some plant-beneficial bacteria with biopesticide potential produce antimicrobial compounds that are tightly involved in multitrophic interactions occurring in the phytosphere among which antagonism toward a diverse range of phytopathogens. However, there is a crucial need for an accurate assessment of antibiotic production rate in this environment colonized by these bacteria. In this context, we conducted the present thesis work with the scope to better understand how two different Bacillus genus strains produce lipopeptides in the rhizosphere of plants. In the first part, one of the strains (B. amyloliquefaciens S499) was selected out of other isolates for its technological traits and in vitro inhibition growth activity of plant pathogenic fungi. We further demonstrated its biocontrol potential in tomato open-field experiments where plantings have been devastated by a local fungus preliminary identified as Fusarium semitectum. In a second part, we combined two mass spectrometry-based approaches (electrospray ionization and imaging) to analyze the pattern of surfactin, iturin and fengycin lipopeptide families produced in planta by strain S499. Our results show that rhizosphere conditions are conducive for surfactin synthesis but not for other types of lipopeptides and that the lipopeptide pattern can be markedly influenced by nutritional factors, biofilm formation and oxygen availability. In a last part, surfactin gene expression (srfA) level was evaluated in situ on tomato root using the reporter gene (LacZ) inserted in B. subtilis strain BGS3. Results showed effective expression of srfA and production of surfactin in biologically important level quantities upon establishment of bacterial population on roots. Our results also demonstrate that BGS3 developing in colonies, efficiently utilizes the main substrates from plant exudates to produce surfactins. The production may also be favored in bacteria growing slowly in the rhizosphere. Globally, this work contributes to better appreciate the impact of some environmental factors on the in situ biosynthesis of lipopeptides by strains of Bacillus which is probably an essential step for improving the level and reliability of their efficacy as biological agents for the control of plant diseases.

tomato plants

Plant-microbe interaction

Bacillus

lipopeptide

synthesis

in situ

production

biocontrol

Fusarium disease

Root exudation

PGPR

Rhizosphere

Biodegradation of xanthate by microbes isolated from a tailings lagoon and a potential role for biofilm and plant/microbe associations /

Lam, Kin-San.

January 1999

Thesis (Ph.D.) -- University of Western Sydney, Nepean, 1999. / Bibliography : p. 213-233.

Vliv rostlin na strukturu, funkci a diverzitu společenstev bakterií / Effects of plants on the structure, function and diversity of bacterial communities

Havlíčková, Petra

January 2018

Vegetation is known to influence the composition of microbial communities. Bacteria can act as roots symbionts or be involved in the decomposition of plant biomass. They can be influenced by soil chemistry but also by plant exudates. Some plants produce targeted exudates to attract specific bacteria to their roots. Bacteria associate with plants frequently but the effect of plant diversity on bacterial communities on their roots and in the surrounding soil remains unclear. The aim of this work was to describe the relationship between the diversity and community composition of bacteria and the diversity of vegetation in forest and grassland ecosystems. The study areas were selected to represent a gradient of vegetation in Bohemian Forest NP and in White Carpathian flowery grasslands. I hypothesized that the diversity and evenness of bacterial community increase with increasing plant diversity. The composition of bacterial community was characterized by 16S rRNA sequencing. The composition of vegetation was determined by phytocenological relevées and by molecular markers trnL. In grassland ecosystem, there was a positive relationship between plant and bacterial diversity only in shoots. The space and vegetation were identified as an important drivers of bacterial community composition in shoots. The...

Interação entre bactérias endofíticas e do rizoplano com Eucalyptus / Interaction between endophytic and rhizoplane bacteria with Eucalyptus

Anderson Ferreira

15 February 2008

Os microrganismos endofíticos são aqueles, cultiváveis ou não, que habitam o interior da planta hospedeira sem causar danos aparentes ou estruturas externas visíveis. Essa interação microrganismos-planta é intrínseca a determinadas espécies de plantas e/ou bactérias. Nas últimas décadas os estudos de microrganismos endofíticos têm sido realizados em diversas plantas hospedeiras, sendo esses estudos direcionados principalmente para a diversidade e características benéficas induzidas, inclusive o controle biológico de doenças. A doença causada pelo fungo Ceratocystis fimbriata é considerada emergente no setor florestal. O Brasil está entre os maiores produtores mundiais de eucalipto e a expansão do setor juntamente com o cultivo clonal tem acarretado o aumento da incidência de patógenos. O surgimento de novas doenças exige estudos relacionados tanto a interação do agente patogênico com hospedeiro quanto de todos os componentes do patossistema. Neste contexto, os microrganismos endofíticos têm sido descritos como potenciais controladores biológicos de doenças. Dessa forma, o presente trabalho teve por objetivos avaliar a interação de C. fimbriata com a comunidade bacteriana associada à Eucalyptus sp. Adicionalmente, foi estudada a possível transferência desses endófitos via sementes e o padrão de colonização de Pantoea agglomerans em plântulas. Foi observado que plantas não infestadas por C. fimbriata apresentaram maior densidade bacteriana no rizoplano (20,66 x 104 UFC.cm2 -1 de raiz), enquanto que para a comunidade endofítica, a maior densidade foi observada em plantas infectadas pelo fungo (25,13 x 104 UFC.g-1 de raiz). As análises por ARDRA possibilitaram a obtenção de 8 e 13 ribotipos nas comunidades endofítica de raiz e do rizoplano, respectivamente. Os ribotipos mais freqüentes foram identificados como Bacillus cereus. As análises de diversidade por meio de DGGE das comunidades do rizoplano e endofítica de raiz mostraram que a infestação pelo fungo interfere na colonização de Eucalyptus. Foi observado também que bactérias endofíticas estão presentes no interior de sementes de Eucalyptus spp. em uma densidade de 0,33 a 1,83 X 102 UFC.g-1, para as espécies E. camandulensis e E. urophylla, respectivamente. A densidade bacteriana endofítica de plântulas obtidas de sementes desinfectadas superficialmente variaram entre 0,27 X 102 a 0,87 X 102 UFC.g-1, para E. citriodora e o híbrido E. robusta x E. grandis, respectivamente. Em algumas espécies de Eucalyptus não foram isoladas bactérias endofíticas das sementes e plântulas. Os resultados mostraram que algumas espécies de bactérias endofíticas podem ser transmitidas verticalmente por sementes. P. agglomerans inoculada nas sementes foi capaz de colonizar as plântulas após a germinação da semente, indicando que esta pode ser uma das formas utilizadas pelos microrganismos para colonizar e se estabelecer na planta hospedeira. Assim, os resultados obtidos neste trabalho mostram ainda que possa existir interação entre a presença de C. fimbriata e a comunidade bacteriana endofítica e do rizoplano de Eucalyptus. Foi possível observar também que estas bactérias endofíticas que são transmitidas por meio de sementes, permitindo que plântulas previamente inoculadas com bactérias benéficas possam ser produzidas antes de serem levadas a campo. / The endophytic microorganisms are those, cultivated or not, that inhabit the interior of the plant host without causing apparent damages or visible external structures. This interaction microorganisms-plant is specific to certain species of plants and/or bacteria. In the last few years studies of endophytic microorganisms have been carried out in several plant hosts, being these studies focused mainly to diversity and biotechnological potential, such as biological control of disease. The disease caused by the phytopathogenic fungi Ceratocystis fimbriata is considered emerging by the reforestation companies. Brazil is one of the largest world eucalyptus producers and the increasing of the eucalyptus production associated to clonal reproduction has allowed the increase in pathogen incidence. Studies that evaluate the interaction between pathogens and the microbial community associated to the host plant may allow understanding how disease symptoms come up. Endophytic microorganisms have been described as potential biological control of diseases and therefore, the aims of the present work were to i) study the interaction between C. fimbriata and the bacterial community associated to the Eucalyptus sp.; ii) evaluate the bacterial dissemination by seeds; iii) evaluate the colonization profile of Pantoea agglomerans in seedlings after seed inoculation. It was observed that the highest bacterial density on the rhizoplane (20.66 x 104 CFU.cm2 -1 of root) was observed in C. fimbriata uninfectedplants, while for endophytic community the highest density was observed in C. fimbriata infected plants (25.13 x 104 CFU.g-1 of root). The ARDRA analyses showed that the bacterial community of eucalyptus is composed by 8 and 13 ribotypes on rhizoplane and inside the roots (endophytic), respectively. The most frequent ribotypes were identified as Bacillus cereus. The DGGE analyses of diversity of endophytic and rhizoplane community showed that fungi infection shift the colonization of Eucalyptus associated bacteria. The bacterial community inside Eucalyptus spp. seeds ranged from 0.33 to 1.83 X 102 CFU.g-1, for E. camandulensis and E. urophylla, respectively. After seed germination the endophytic bacterial density in seedlings ranged from 0,27 X 102 to 0,87 X 102 CFU.g-1, for E. citriodora and the hybrid E. robusta x E. grandis, respectively. Although, endophytic bacteria have been isolated from seeds, for some plant species, bacteria were not isolated from seedlings. Also, some bacteria may be vertically transmitted from seed to seedlings, but some is specific for seeds. Seed inoculation of P. agglomerans resulted in seedlings colonized by these bacteria, suggesting that these bacteria could be seed transmitted. The results obtained in the present study show that the fungi C. fimbriata inside the Eucalyptus host can shift the endophytic and rhizoplane bacterial diversity. Also, these endophytic bacteria could be transmitted vertically by seeds, allowing that seeds previously inoculated with beneficial bacteria may result in protected plants before planting in the field.

Bactérias

Ecologia microbiana

Eucalipto

Fungos fitopatogênicos

Microrganismos endofíticos.

16S rDNA

DGGE

Fluorescence microscopy.

Microbial ecology

Plant microbe interctions