Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2024 |
| Tipo de documento: | Tese |
| Idioma: | eng |
| Título da fonte: | Biblioteca Digital de Teses e Dissertações da USP |
| Texto Completo: | https://www.teses.usp.br/teses/disponiveis/11/11137/tde-09102024-085012/ |
Resumo: | Witches\' broom disease (WBD) of cacao (Theobroma cacao), caused by the hemibiotrophic fungus Moniliophthora perniciosa, poses a significant global threat to cacao production. Isolates of M. perniciosa can be categorized into biotypes based on host specificity: the C-biotype infects cacao, the L-biotype colonizes wild lianas, and the S-biotype infects solanaceous species, with limited cross-infection. Typical symptoms include loss of apical dominance and hypertrophic growth of axillary shoots. The use of tomato (Solanum lycopersicum) cv. Micro-Tom (MT) as a model enables the study of M. perniciosa interactions. In Chapter VII, we investigated the hormonal changes associated with these symptoms in MT, demonstrating that the S-biotype produces cytokinins (CKs) in vitro, potentially disrupting cytokinin balance in infected plants, as evidenced by elevated CK levels in the thickened, infected stems. MT lines overexpressing the Arabidopsis CYTOKININ OXIDASE-2 (35S::AtCKX2), which reduces CK levels, showed decreased symptom severity and infection incidence. Additionally, synthetic CK treatments mimicked disease symptoms, while CK perception inhibitors reduced symptoms. In Chapter VI, we demonstrated that infection in MT enhances sink strength in symptomatic stems, an effect absent in 35S::AtCKX2 lines, implicating CKs in the formation of a nutrient sink. These symptoms led to significant metabolic and physiological changes, reducing fruit yield and potentially reinforcing secondary cell walls and producing lignin, likely serving as a nutritional resource for the pathogen during the necrotrophic phase. Chapter V explored the indirect effects of infection in root development. We observed reduced root biomass coinciding with increased stem diameter after infection, with lateral root elongation being primarily affected. Hormonal imbalances could not fully explain this impairment; infected roots showed reduced levels of carbohydrate and amino acids, and a 13C-CO2 fixation assay revealed decreased carbon allocation to roots after infection. Sucrose supplementation in vitro partially restored lateral root growth, suggesting that reduced root biomass results from decreased photoassimilate supply, which might impair water and nutrient uptake and contribute to reduced host yield. Building on symptom development, Chapter II utilized the MT model to investigate fungal pathogenesis and plant defense responses by comparing MT infection by either the S-biotype (compatible) or the C-biotype (incompatible) of M. perniciosa. Our findings revealed common early transcriptional immune responses, particularly in pattern-triggered immunity (PTI) signaling and cell wall reinforcement, with stronger expression during the incompatible interaction, indicating more robust defenses. This aligns with pre- and co-inoculation assays demonstrating a priming response to the compatible pathogen. Fungal gene expression revealed presumed effectors and other genes involved in pathogenesis in cacao during early infection of MT. Hormonal responses, particularly jasmonic acid (JA) and ethylene (ET), were implicated in the infection process, with ET remarkably playing a role in inducing resistance to S_biotype M. perniciosa in MT. In Chapter III, we introduced Nicotiana benthamiana as a novel model host for M. perniciosa and conducted comparative transcriptional and functional profiling. N. benthamiana is susceptible to both S- and C- biotypes, though one S-biotype isolate (Tiradentes) showed incompatibility, challenging the classical view of M. perniciosa biotype classification. Early transcriptional responses to inoculation revealed shared immune responses to both biotypes, with quicker and stronger defenses in the incompatible interaction. Suppression of immune responses was observed at 72 hours after inoculation, coinciding with the expression of several fungal genes also active in cacao infections. Functional analyses suggested that TIR-NLR-related effector-triggered immunity (ETI) may not be essential for infection by the incompatible biotype in N. benthamiana, and we suspect that PTI could be involved. Additionally, in Chapter IV, we identified four effector candidates expressed in N. benthamiana that exhibited antimicrobial activity, potentially modulating the host microbiota during colonization. Characterizing symptom development, identifying early defense response components, and understanding fungal pathogenesis are crucial steps toward developing strategies to enhance cacao resistance to M. perniciosa. |
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Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom diseaseDissecando a especificidade do hospedeiro na patogênese dos isolados dos biótipos-S e C de Moniliophthora perniciosa, o agente causador da vassoura-de-bruxa do cacaueiroFungoFungusHost-pathogen interactionImmune responseInteração hospedeiro-patógenoPathogenesisPatogêneseResposta imuneWitches\' broom disease (WBD) of cacao (Theobroma cacao), caused by the hemibiotrophic fungus Moniliophthora perniciosa, poses a significant global threat to cacao production. Isolates of M. perniciosa can be categorized into biotypes based on host specificity: the C-biotype infects cacao, the L-biotype colonizes wild lianas, and the S-biotype infects solanaceous species, with limited cross-infection. Typical symptoms include loss of apical dominance and hypertrophic growth of axillary shoots. The use of tomato (Solanum lycopersicum) cv. Micro-Tom (MT) as a model enables the study of M. perniciosa interactions. In Chapter VII, we investigated the hormonal changes associated with these symptoms in MT, demonstrating that the S-biotype produces cytokinins (CKs) in vitro, potentially disrupting cytokinin balance in infected plants, as evidenced by elevated CK levels in the thickened, infected stems. MT lines overexpressing the Arabidopsis CYTOKININ OXIDASE-2 (35S::AtCKX2), which reduces CK levels, showed decreased symptom severity and infection incidence. Additionally, synthetic CK treatments mimicked disease symptoms, while CK perception inhibitors reduced symptoms. In Chapter VI, we demonstrated that infection in MT enhances sink strength in symptomatic stems, an effect absent in 35S::AtCKX2 lines, implicating CKs in the formation of a nutrient sink. These symptoms led to significant metabolic and physiological changes, reducing fruit yield and potentially reinforcing secondary cell walls and producing lignin, likely serving as a nutritional resource for the pathogen during the necrotrophic phase. Chapter V explored the indirect effects of infection in root development. We observed reduced root biomass coinciding with increased stem diameter after infection, with lateral root elongation being primarily affected. Hormonal imbalances could not fully explain this impairment; infected roots showed reduced levels of carbohydrate and amino acids, and a 13C-CO2 fixation assay revealed decreased carbon allocation to roots after infection. Sucrose supplementation in vitro partially restored lateral root growth, suggesting that reduced root biomass results from decreased photoassimilate supply, which might impair water and nutrient uptake and contribute to reduced host yield. Building on symptom development, Chapter II utilized the MT model to investigate fungal pathogenesis and plant defense responses by comparing MT infection by either the S-biotype (compatible) or the C-biotype (incompatible) of M. perniciosa. Our findings revealed common early transcriptional immune responses, particularly in pattern-triggered immunity (PTI) signaling and cell wall reinforcement, with stronger expression during the incompatible interaction, indicating more robust defenses. This aligns with pre- and co-inoculation assays demonstrating a priming response to the compatible pathogen. Fungal gene expression revealed presumed effectors and other genes involved in pathogenesis in cacao during early infection of MT. Hormonal responses, particularly jasmonic acid (JA) and ethylene (ET), were implicated in the infection process, with ET remarkably playing a role in inducing resistance to S_biotype M. perniciosa in MT. In Chapter III, we introduced Nicotiana benthamiana as a novel model host for M. perniciosa and conducted comparative transcriptional and functional profiling. N. benthamiana is susceptible to both S- and C- biotypes, though one S-biotype isolate (Tiradentes) showed incompatibility, challenging the classical view of M. perniciosa biotype classification. Early transcriptional responses to inoculation revealed shared immune responses to both biotypes, with quicker and stronger defenses in the incompatible interaction. Suppression of immune responses was observed at 72 hours after inoculation, coinciding with the expression of several fungal genes also active in cacao infections. Functional analyses suggested that TIR-NLR-related effector-triggered immunity (ETI) may not be essential for infection by the incompatible biotype in N. benthamiana, and we suspect that PTI could be involved. Additionally, in Chapter IV, we identified four effector candidates expressed in N. benthamiana that exhibited antimicrobial activity, potentially modulating the host microbiota during colonization. Characterizing symptom development, identifying early defense response components, and understanding fungal pathogenesis are crucial steps toward developing strategies to enhance cacao resistance to M. perniciosa.A vassoura-de-bruxa (VDB) do cacau (Theobroma cacao), causada pelo fungo hemibiotrófico Moniliophthora perniciosa, representa uma ameaça global significativa à produção de cacau. Os isolados de M. perniciosa podem ser categorizados em biótipos com base na especificidade do hospedeiro: o biótipo-C infecta o cacau, o biótipo-L coloniza lianas silvestres, e o biótipo-S infecta espécies de solanáceas, com infecção cruzada limitada. Os sintomas típicos incluem perda da dominância apical e crescimento hipertrófico de brotos axilares. O uso do tomate (Solanum lycopersicum) cv. Micro-Tom (MT) como modelo permite o estudo das interações com M. perniciosa. No Capítulo VII, investigamos as mudanças hormonais associadas a esses sintomas em MT, demonstrando que o biótipo-S produz citocininas (CKs) in vitro, potencialmente desregulando o balanço de CKs nas plantas infectadas, como evidenciado pelos níveis elevados de CKs nos caules espessados e infectados. Linhas de MT superexpressando a CYTOKININ OXIDASE-2 de Arabidopsis (35S::AtCKX2), que reduzem os níveis de CKs, apresentaram menor severidade dos sintomas e incidência de infecção. Além disso, tratamentos com CK sintética mimetizaram os sintomas da doença, enquanto inibidores de percepção de CKs reduziram os sintomas. No Capítulo VI, demonstramos que a infecção em MT aumenta a força de dreno nos caules sintomáticos, efeito ausente nas linhas 35S::AtCKX2, implicando as CKs na formação de um dreno de nutrientes. Esses sintomas levaram a alterações metabólicas e fisiológicas significativas, reduzindo a produção de frutos e potencialmente reforçando as paredes celulares secundárias e produzindo lignina, o que provavelmente serve como recurso nutricional para o patógeno durante a fase necrotrófica. O Capítulo V explorou os efeitos indiretos da infecção no desenvolvimento radicular. Observamos redução da biomassa radicular coincidindo com o aumento do diâmetro do caule após a infecção, afetando significativamente o crescimento de raízes laterais. Alterações em níveis/percepção hormonais não foram suficientes para elucidar o reduzido crescimento das raízes; entretanto, raízes de plantas infectadas apresentaram níveis reduzidos de carboidratos e aminoácidos, e um ensaio de fixação de 13CO2 revelou uma diminuição na alocação de carbono para as raízes após a infecção. A suplementação de sacarose in vitro restaurou parcialmente o crescimento das raízes laterais, sugerindo que a redução da biomassa radicular resulta da diminuição do suprimento de fotoassimilados, o que pode prejudicar a absorção de água e nutrientes, contribuindo para a queda na produtividade do hospedeiro. Após a investigação do desenvolvimento de sintomas, no Capítulo II foi reportado o estudo do modelo MT para investigar a patogênese e as respostas de defesa da planta comparando a infecção de MT por isolados dos biótipos-S (compatível) e -C (incompatível) de M. perniciosa. Nossos resultados revelaram respostas imunológicas transcricionais comuns nas fases iniciais, particularmente na sinalização de imunidade desencadeada por padrões (PTI) e no reforço da parede celular, com uma expressão mais robusta durante a interação incompatível, indicando respostas de defesa mais robustas. Isso corrobora os ensaios de pré-inoculação e co-inoculação com o biótipo incompatível, demonstrando uma resposta de priming ao patógeno compatível. A expressão de genes do fungo revelou candidatos efetores e outros genes envolvidos na patogênese no cacau durante a infecção precoce em MT. Respostas hormonais, particularmente ácido jasmônico (JA) e etileno (ET), foram implicadas na infecção, com ET desempenhando um papel notável na indução de resistência ao biótipo-S em MT. No Capítulo III, revelamos Nicotiana benthamiana como um novo hospedeiro modelo para M. perniciosa e realizamos perfis comparativos transcricionais e funcionais. N. benthamiana é suscetível a ambos os biótipos C e S, embora um isolado do biótipo S (Tiradentes) tenha mostrado incompatibilidade, desafiando a visão clássica da classificação dos biótipos de M. perniciosa. Análises transcricionais revelaram respostas imunes compartilhadas a ambos os biótipos, com defesas mais rápidas e fortes na interação incompatível. A supressão de respostas imunes foi observada 72 horas após a inoculação, coincidindo com a expressão de vários genes do patógeno também ativos em infecções de cacau. As análises funcionais sugeriram que a imunidade relacionada ao TIR-NLR (ETI) pode não ser essencial para a infecção pelo biótipo incompatível em N. benthamiana, e suspeitamos que a PTI poderia estar envolvida. Além disso, no Capítulo IV, identificamos quatro candidatos a efetores expressos em N. benthamiana que exibiram atividade antimicrobiana, potencialmente modulando a microbiota do hospedeiro durante a colonização. Caracterizar o desenvolvimento dos sintomas, identificar componentes precoces das respostas de defesa e compreender a patogênese fúngica são etapas cruciais para o desenvolvimento de estratégias que aumentem a resistência do cacau a M. perniciosa.Biblioteca Digitais de Teses e Dissertações da USPFigueira, Antonio Vargas de OliveiraPaschoal, Daniele2024-07-19info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/doctoralThesisapplication/pdfhttps://www.teses.usp.br/teses/disponiveis/11/11137/tde-09102024-085012/reponame:Biblioteca Digital de Teses e Dissertações da USPinstname:Universidade de São Paulo (USP)instacron:USPReter o conteúdo por motivos de patente, publicação e/ou direitos autoriais.info:eu-repo/semantics/openAccesseng2024-10-10T13:04:02Zoai:teses.usp.br:tde-09102024-085012Biblioteca Digital de Teses e Dissertaçõeshttp://www.teses.usp.br/PUBhttp://www.teses.usp.br/cgi-bin/mtd2br.plvirginia@if.usp.br|| atendimento@aguia.usp.br||virginia@if.usp.bropendoar:27212024-10-10T13:04:02Biblioteca Digital de Teses e Dissertações da USP - Universidade de São Paulo (USP)false |
| dc.title.none.fl_str_mv |
Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease Dissecando a especificidade do hospedeiro na patogênese dos isolados dos biótipos-S e C de Moniliophthora perniciosa, o agente causador da vassoura-de-bruxa do cacaueiro |
| title |
Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease |
| spellingShingle |
Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease Paschoal, Daniele Fungo Fungus Host-pathogen interaction Immune response Interação hospedeiro-patógeno Pathogenesis Patogênese Resposta imune |
| title_short |
Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease |
| title_full |
Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease |
| title_fullStr |
Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease |
| title_full_unstemmed |
Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease |
| title_sort |
Dissecting host specificity in the pathogenesis of S- and C-biotype isolates of Moniliophthora perniciosa, the causal agent of cacao witches\' broom disease |
| author |
Paschoal, Daniele |
| author_facet |
Paschoal, Daniele |
| author_role |
author |
| dc.contributor.none.fl_str_mv |
Figueira, Antonio Vargas de Oliveira |
| dc.contributor.author.fl_str_mv |
Paschoal, Daniele |
| dc.subject.por.fl_str_mv |
Fungo Fungus Host-pathogen interaction Immune response Interação hospedeiro-patógeno Pathogenesis Patogênese Resposta imune |
| topic |
Fungo Fungus Host-pathogen interaction Immune response Interação hospedeiro-patógeno Pathogenesis Patogênese Resposta imune |
| description |
Witches\' broom disease (WBD) of cacao (Theobroma cacao), caused by the hemibiotrophic fungus Moniliophthora perniciosa, poses a significant global threat to cacao production. Isolates of M. perniciosa can be categorized into biotypes based on host specificity: the C-biotype infects cacao, the L-biotype colonizes wild lianas, and the S-biotype infects solanaceous species, with limited cross-infection. Typical symptoms include loss of apical dominance and hypertrophic growth of axillary shoots. The use of tomato (Solanum lycopersicum) cv. Micro-Tom (MT) as a model enables the study of M. perniciosa interactions. In Chapter VII, we investigated the hormonal changes associated with these symptoms in MT, demonstrating that the S-biotype produces cytokinins (CKs) in vitro, potentially disrupting cytokinin balance in infected plants, as evidenced by elevated CK levels in the thickened, infected stems. MT lines overexpressing the Arabidopsis CYTOKININ OXIDASE-2 (35S::AtCKX2), which reduces CK levels, showed decreased symptom severity and infection incidence. Additionally, synthetic CK treatments mimicked disease symptoms, while CK perception inhibitors reduced symptoms. In Chapter VI, we demonstrated that infection in MT enhances sink strength in symptomatic stems, an effect absent in 35S::AtCKX2 lines, implicating CKs in the formation of a nutrient sink. These symptoms led to significant metabolic and physiological changes, reducing fruit yield and potentially reinforcing secondary cell walls and producing lignin, likely serving as a nutritional resource for the pathogen during the necrotrophic phase. Chapter V explored the indirect effects of infection in root development. We observed reduced root biomass coinciding with increased stem diameter after infection, with lateral root elongation being primarily affected. Hormonal imbalances could not fully explain this impairment; infected roots showed reduced levels of carbohydrate and amino acids, and a 13C-CO2 fixation assay revealed decreased carbon allocation to roots after infection. Sucrose supplementation in vitro partially restored lateral root growth, suggesting that reduced root biomass results from decreased photoassimilate supply, which might impair water and nutrient uptake and contribute to reduced host yield. Building on symptom development, Chapter II utilized the MT model to investigate fungal pathogenesis and plant defense responses by comparing MT infection by either the S-biotype (compatible) or the C-biotype (incompatible) of M. perniciosa. Our findings revealed common early transcriptional immune responses, particularly in pattern-triggered immunity (PTI) signaling and cell wall reinforcement, with stronger expression during the incompatible interaction, indicating more robust defenses. This aligns with pre- and co-inoculation assays demonstrating a priming response to the compatible pathogen. Fungal gene expression revealed presumed effectors and other genes involved in pathogenesis in cacao during early infection of MT. Hormonal responses, particularly jasmonic acid (JA) and ethylene (ET), were implicated in the infection process, with ET remarkably playing a role in inducing resistance to S_biotype M. perniciosa in MT. In Chapter III, we introduced Nicotiana benthamiana as a novel model host for M. perniciosa and conducted comparative transcriptional and functional profiling. N. benthamiana is susceptible to both S- and C- biotypes, though one S-biotype isolate (Tiradentes) showed incompatibility, challenging the classical view of M. perniciosa biotype classification. Early transcriptional responses to inoculation revealed shared immune responses to both biotypes, with quicker and stronger defenses in the incompatible interaction. Suppression of immune responses was observed at 72 hours after inoculation, coinciding with the expression of several fungal genes also active in cacao infections. Functional analyses suggested that TIR-NLR-related effector-triggered immunity (ETI) may not be essential for infection by the incompatible biotype in N. benthamiana, and we suspect that PTI could be involved. Additionally, in Chapter IV, we identified four effector candidates expressed in N. benthamiana that exhibited antimicrobial activity, potentially modulating the host microbiota during colonization. Characterizing symptom development, identifying early defense response components, and understanding fungal pathogenesis are crucial steps toward developing strategies to enhance cacao resistance to M. perniciosa. |
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2024 |
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2024-07-19 |
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info:eu-repo/semantics/doctoralThesis |
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https://www.teses.usp.br/teses/disponiveis/11/11137/tde-09102024-085012/ |
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eng |
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Reter o conteúdo por motivos de patente, publicação e/ou direitos autoriais. |
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Biblioteca Digitais de Teses e Dissertações da USP |
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Biblioteca Digitais de Teses e Dissertações da USP |
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