The Eucalyptus Cuticular Waxes Contribute in Preformed Defense Against Austropuccinia psidii

Austropuccinia psidii, the causal agent of myrtle rust, is a biotrophic pathogen whose growth and development depends on the host tissues. The uredospores of A. psidii infect Eucalyptus by engaging in close contact with the host surface and interacting with the leaf cuticle that provides important chemical and physical signals to trigger the infection process. In this study, the cuticular waxes of Eucalyptus spp. were analyzed to determine their composition or structure and correlation with susceptibility/resistance to A. psidii. Twenty-one Eucalyptus spp. in the field were classified as resistant or susceptible. The resistance/susceptibility level of six Eucalyptus spp. were validated in controlled conditions using qPCR, revealing that the pathogen can germinate on the eucalyptus surface of some species without multiplying in the host. CG-TOF-MS analysis detected 26 compounds in the Eucalyptus spp. cuticle and led to the discovery of the role of hexadecanoic acid in the susceptibility of Eucalyptus grandis and Eucalyptus phaeotricha to A. psidii. We characterized the epicuticular wax morphology of the six previously selected Eucalyptus spp. using scanning electron microscopy and observed different behavior in A. psidii germination during host infection. It was found a correlation of epicuticular morphology on the resistance to A. psidii. However, in this study, we provide the first report of considerable interspecific variation in Eucalyptus spp. on the susceptibility to A. psidii and its correlation with cuticular waxes chemical compounds that seem to play a synergistic role as a preformed defense mechanism

Molecular study of the development of Puccinia psidii Winter in vitro and during its infection in Eucalyptus grandis

O Brasil é um dos principais produtores mundiais de Eucalyptus spp., mas a produção dessa cultura tem sido comprometida por perdas causadas pelo fungo Puccinia psidii Winter, agente causal da ferrugem do eucalipto. Compreender os mecanismos moleculares da patogenicidade desse fungo, conhecer a composição química de variedades de Eucalyptus spp. resistentes e suscetíveis ao fitopatógeno e ter em mãos uma ferramenta de diagnóstico precoce da doença são conhecimentos de fundamental importância para o desenvolvimento de estratégias de controle do fitopatógeno. Uma das principais barreiras que limitam o estudo molecular de P. psidii é o fato dessa espécie ser biotrófica obrigatória, tendo seu desenvolvimento in vitro limitado. Estudos de investigação a respeito de fungos biotróficos obrigatórios são realizados principalmente in planta e em estágios tardios da doença, deixando grande parte do conhecimento dos processos iniciais de infecção desconhecidos. Informações a respeito dos estágios iniciais da infecção, nos quais diversas estruturas típicas são formadas e podem indicar importantes características sobre fungos biotróficos, são de difícil acesso em estudos in planta em função da grande quantidade de material vegetal em relação à quantidade de material do fitopatógeno, que não é passível de ser removido completamente das amostras analisadas. Dessa forma, o presente projeto de pesquisa foi realizado com os objetivos de desenvolver um protocolo para induzir a germinação e a morfogênese estrutural in vitro de P. psidii, identificar genes candidatos relacionados à diferenciação das estruturas de infecção e de fatores de virulência, caracterizar os metabólitos presentes nas ceras cuticulares de folhas de Eucalyptus grandis resistentes e suscetíveis à ferrugem do eucalipto e desenvolver uma metodologia sensível e eficaz para detectar, quantificar e monitorar a presença de P. psidii em folhas de Eucalyptus grandis assintomáticas. Os dados obtidos no presente trabalho podem auxiliar a compreensão da interação planta-patógeno durante os estágios iniciais de infecção da ferrugem e colaboram para o entendimento da biologia do fitopatógeno para que no futuro sejam desenvolvidas melhores estratégias de controle de P. psidii em plantios de eucalipto.Brazilian production of Eucalyptus spp. is one of the greatest in the world but it has been affected by Puccinia psidii Winter, the causal agent of eucalyptus rust. The comprehension of molecular mechanisms of pathogenicity and chemical composition of resistant and susceptible eucalyptus plants as well as having a molecular tool for early detection of the disease in field can be used for the development of improved control strategies against this phytopathogen. Molecular studies of P. psidii is limited because it is an obligate biotrophic fungus with limited in vitro development. Biotrophic fungi investigations are made mainly in planta at late developmental stages of the disease. This way, most information of early stages of infection as the development of specialized structures of biotrophic fungi are little understood. The study of early stages of the infection process of biotrophic fungi in planta is hampered by the high amount of plant material in relation to fungi material which is difficult to be obtained in an isolated form for analysis. In this work we developed a protocol to increase in vitro germination and structural differentiation of P. psidii and used this protocol to obtain isolated fungi material for the identification of candidate genes related with virulence factors and initial structural morphogenesis. Moreover, we analyzed the composition of metabolites present in the cuticular wax of leaves from resistant and susceptible E. grandis plants and developed a methodology for the detection of P. psidii in asymptomatic leaves of Eucalyptus grandis. Data obtained in this work help the comprehension of E. grandis-P.psidii interaction at early stages of the infection process and can be used for the development of improved control strategies of eucalyptus rust

Label-Free Quantitative Proteomic Analysis of <i>Puccinia psidii</i> Uredospores Reveals Differences of Fungal Populations Infecting Eucalyptus and Guava

<div><p><i>Puccinia psidii</i> sensu lato (s.l.) is the causal agent of eucalyptus and guava rust, but it also attacks a wide range of plant species from the myrtle family, resulting in a significant genetic and physiological variability among populations accessed from different hosts. The uredospores are crucial to <i>P</i>. <i>psidii</i> dissemination in the field. Although they are important for the fungal pathogenesis, their molecular characterization has been poorly studied. In this work, we report the first in-depth proteomic analysis of <i>P</i>. <i>psidii</i> s.l. uredospores from two contrasting populations: guava fruits (PpGuava) and eucalyptus leaves (PpEucalyptus). NanoUPLC-MS^E was used to generate peptide spectra that were matched to the UniProt <i>Puccinia</i> genera sequences (UniProt database) resulting in the first proteomic analysis of the phytopathogenic fungus <i>P</i>. <i>psidii</i>. Three hundred and fourty proteins were detected and quantified using Label free proteomics. A significant number of unique proteins were found for each sample, others were significantly more or less abundant, according to the fungal populations. In PpGuava population, many proteins correlated with fungal virulence, such as malate dehydrogenase, proteossomes subunits, enolases and others were increased. On the other hand, PpEucalyptus proteins involved in biogenesis, protein folding and translocation were increased, supporting the physiological variability of the fungal populations according to their protein reservoirs and specific host interaction strategies.</p></div

Proteins identified from <i>P</i>. <i>psidii</i> uredospore populations.

<p>The proteins exclusively found in PpGuava (right) and PpEucalyptus (left) and common to both populations (center). Of the common proteins, 25 and 120 whose abundance were increased in PpEucalyptus and PpGuava, respectively.</p

Gene ontology of biological process terms in the proteomic analysis.

<p>Bar graph represents the ratio of % composition of term in the proteomic data.</p

Morphological and viability analysis of <i>Puccinia psidii</i> uredospores.

<p><i>P</i>. <i>psidii</i> uredospores from <i>E</i>. <i>grandis</i><b>(A)</b> and <i>P</i>. <i>guajava</i><b>(B)</b> exhibit similar morphology and germination viability, respectively <b>(C and D)</b>.The arrows indicate the fungal germ tube in both uredospore populations, 24 hours after inoculation in water-agar medium. Light microscopy images of PpEucalyptus and PpGuava uredospores are shown at 100 X (A and B) and 200 X (C and D) magnification. Scale bar: 20 μm in A and B, 50 μm in C and D.</p

Eucalyptus infection by guava and eucalyptus rust.

<p>Symptoms induced by inoculation of <i>P</i>. <i>psidii</i> uredospores from PpEucalyptus <b>(A)</b> on <i>E</i>. <i>grandis</i> variety D901. This clone is rust susceptible when grown under field conditions. The white arrows indicate the fungal pustules. The leaves are shown 15 days after inoculation.The PpGuava populations <b>(B)</b> and control <b>(C)</b> did not show typical rust symptoms.</p

Protein profiles in PpGuava and PpEucalyptus and the correlation with their physiological variability.

<p>While proteins correlated to fungal virulence and stress response had the abundance increased in PpGuava, proteins related to biogenesis, protein folding and translation had the abundance increased in PpEucalyptus.</p