Native forest pathogens may facilitate persistence of Douglas-fir in old-growth forests of northwestern California /

Hawkins, Ashley E.

Unknown Date

Thesis (M.A.)--Humboldt State University, 2009. / Includes bibliographical references (leaves 37-42). Also available via Humboldt Digital Scholar.

Anatomia e ultraestrutura do processo de infecção de Xanthomonas causadoras de doenças em citros / Anatomy and ultrastructure of Xanthomonas infectious process causing diseases in citrus

Vieira, Flávia Campos Freitas [UNESP]

04 June 2018

Submitted by FLÁVIA CAMPOS FREITAS VIEIRA (flavia.camposfv@yahoo.com.br) on 2018-06-28T14:09:18Z No. of bitstreams: 1 Tese_Flávia_Vieira_2018.pdf: 8871588 bytes, checksum: e1ee1b7f2e2e7170f04d44c1a1e76d6a (MD5) / Approved for entry into archive by Neli Silvia Pereira null (nelisps@fcav.unesp.br) on 2018-06-29T18:42:12Z (GMT) No. of bitstreams: 1 vieira_fcf_dr_jabo.pdf: 8871588 bytes, checksum: e1ee1b7f2e2e7170f04d44c1a1e76d6a (MD5) / Made available in DSpace on 2018-06-29T18:42:12Z (GMT). No. of bitstreams: 1 vieira_fcf_dr_jabo.pdf: 8871588 bytes, checksum: e1ee1b7f2e2e7170f04d44c1a1e76d6a (MD5) Previous issue date: 2018-06-04 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Os citros são um grupo de espécies vegetais, com alto potencial produtivo, porém, acometido por várias doenças. Do gênero de bactérias Xanthomonas, três espécies são patogênicas a citros: Xanthomonas citri subsp. citri, agente causal do cancro cítrico, uma das doenças de maior preocupação da citricultura; X. fuscans subsp. aurantifolii tipos B e C, que causam a cancrose; e X. alfalfae subsp. citrumelonis, responsável por causar a mancha bacteriana dos citros. Diante disso, o objetivo desse trabalho foi a análise e descrição, em nível anatômico e ultraestrutural, dos processos de infecção de bactérias do gênero Xanthomonas, causadoras de doenças em citros, a correlação do fenótipo da interação XfaC-citros com o transcriptoma e a análise dos fatores de virulência das estirpes estudadas. O processo de infecção das estirpes Xac306, Xac636, Xac828, Xacm1510, XfaC1632 e XfaC1630 em lima ácida ‘Galego’ e/ou laranja doce ‘Hamlin’, foi avaliado em diferentes períodos de infecção, pelas técnicas de microscopia de luz e eletrônicas de varredura e transmissão. As seguintes características relacionadas a virulência das estirpes foram avaliadas: formação in vitro de biofilme, produção de goma, motilidade “swimming” e auto agregação celular. Os resultados mostraram que Xac306 é a estirpe mais agressiva dentre as demais, visto pelos sintomas e pela intensidade das alterações anatômicas no tecido de ‘Hamlin’ e ‘Galego’. O processo de infecção em lima ácida ‘Galego’ foi semelhante em todas as estirpes de Xanthomonas estudadas, pois induziram hiperplasia e hipertrofia, porém, em diferentes intensidades, sendo que as alterações provocadas pelas estirpes Xac828 e Xacm1510 não resultaram no rompimento da epiderme; todas as estirpes produziram goma, envolvendo as bactérias e favorecendo a colonização no ambiente intercelular. A microscopia de luz permitiu identificar alterações na anatomia de lima ácida ‘Galego’ infectada e a diferença de susceptibilidade entre as variedades de citros inoculadas com Xac306 e estirpes de XfaC. As microscopias eletrônicas de varredura e transmissão permitiram a identificação de aspectos em comum às estirpes, independente da variedade cítrica. A HR induzida por estirpes de XfaC foi caracterizada pela microscopia eletrônica de transmissão. Com a análise de microscopia, não foi possível estabelecer uma relação direta entre os testes de formação in vitro de biofilme, produção de goma e motilidade “swimming” das estirpes. A análise dos dados de transcriptoma revelou que a resposta de defesa de laranja ‘Hamlin’ contra XfaC foi uma resposta rápida e eficiente que levou a indução de HR, que em última instância, conteve a infecção pela morte celular programada no local da infecção. Esse trabalho ampliou o conhecimento da área sobre o comportamento de diferentes estirpes de Xanthomonas causadoras de doenças em citros, fornecendo informações sobre sua interação com o hospedeiro suscetível e a resposta de defesa de XfaC em interação incompatível. / Citrus are a diverse group of plant species, with high yield potential, but affected by several diseases. The bacteria genus Xanthomonas has three species pathogenic to citrus: Xanthomonas citri subsp. citri, causal agent of citrus canker, one of the most important diseases of citrus crop; X. fuscans subsp. aurantifolii types B and C, causing citrus cancrosis; and X. alfalfae subsp. citrumelonis, which causes citrus bacterial spot. Therefore, the goal of this work was to analyze and describe, at the anatomical and ultrastructural level the infectious processes of Xanthomonas causing diseases in citrus, the correlation of the XfaC-citrus interaction phenotype with the transcriptome and the comparative analysis of virulence related factors, in order to elucidate morphophysiological traits of host-pathogen interaction. The infection process of Xac306, Xac636, Xac828, Xacm1510, XfaC1632 and XfaC1630 strains in 'Galego' Mexican lime and 'Hamlin' sweet orange were evaluated at different points of infection by light microscopy and scanning and transmission electron microscopy. The following virulence related characteristics of the strains were evaluated: in vitro biofilm formation, gum production, swimming motility and cellular auto aggregation. The results showed that Xac306 is the most aggressive strain among the others, due to the intensity of the symptoms and anatomical alterations in 'Hamlin' and 'Galego' tissue. The infection process in the susceptible host ('Galego' Mexican lime) was similar for all Xanthomonas strains studied, since they induced hyperplasia and hypertrophy, however in different intensities, and the alterations caused by Xac828 and Xacm1510 strains did not result in epidermis rupture; all strains produce gum, involving bacteria and assisting colonization in the intercellular environment. Light microscopy was able to identify anatomical alterations in 'Galego' Mexican lime infected tissue and the susceptibility differences between citrus varieties inoculated with Xac306 and XfaC strains. The scanning and transmission electron microscopies was able to identify common traits to the strains, regardless of the citrus variety. The HR induced by XfaC strains was characterized by transmission electron microscopy. We could not stablish a direct relation between the in vitro biofilm formation, gum production and "swimming" motility of the strains with the microscopy analysis. The transcriptome analysis revealed that 'Hamlin' defense response against XfaC is a quick and effective response that led to an HR induction, which ultimately contained the infection, by programmed cell death at the site of infection. This work expanded our knowledge about the behavior of different Xanthomonas strains causing citrus diseases, providing information on its interaction with the susceptible host and the defense response of XfaC in an incompatible interaction.

Interação planta-patógeno

Cancro cítrico

Patogenicidade

Resposta de hipersensibilidade

Microscopia eletrônica

Plant-pathogen interaction

Citrus canker

Electron microscopy

Pathogenicity

Hypersensitivity response

Estudos funcionais de proteínas cerato-plataninas e Necrosis- and Ethylene-inducing Proteins do fungo causador da vassoura-de-bruxa do cacaueiro, Moniliophthora perniciosa = Functional studies on cerato-platanins and necrosis- and ethyleneinducing proteins from the causal agent from the witches' broom disease of cocoa, Moniliophthora perniciosa / Functional studies on cerato-platanins and necrosis- and ethyleneinducing proteins from the causal agent from the witches' broom disease of cocoa, Moniliophthora perniciosa

Barsottini, Mario Ramos de Oliveira, 1987-

23 August 2018

Orientadores: Gonçalo Amarante Guimarães Pereira, Sandra Martha Gomes Dias / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-23T22:03:27Z (GMT). No. of bitstreams: 1 Barsottini_MarioRamosdeOliveira_M.pdf: 16356564 bytes, checksum: 9cf8e738f13f95639e35471c9a7da160 (MD5) Previous issue date: 2013 / Resumo: O fungo Moniliophthora perniciosa desperta grande interesse agroeconômico, pois é o agente etiológico da Vassoura-de-Bruxa do cacau. A cultura do cacaueiro é de grande importância no cenário nacional e na América Latina, sendo o entendimento dos mecanismos moleculares desta doença de grande valia. Durante a interação entre patógeno e hospedeiro, o primeiro produz moléculas para evadir ou alterar as respostas normais de defesa do segundo. O sequenciamento do genoma de M. perniciosa levou à identificação de proteínas-chave potencialmente envolvidas no processo patogênico do fungo, dentre as quais, estão: proteínas pertencentes à família das Cerato-plataninas (MpCPs), bem como proteínas pertencentes à família das Necrosis- and Ethylene-inducing Proteins (MpNEPs). As CPs são amplamente associadas à interação fungo-hospedeiro, agindo como toxinas, indutoras de resposta de defesa ou alergenos. As NEPs induzem morte celular e necrose em plantas dicotiledônes através da permeabilização da membrana celular. O objetivo desse projeto foi caracterizar funcionalmente as MpCPs e as MpNEPs, determinando assim sua relevância durante a Vassoura-de-Bruxa. A partir do transcriptoma de M. perniciosa e da análise filogenética das doze MpCPs encontradas, foi revelada uma correlação entre grupos de MpCPs e sua expressão diferencial ao longo da doença. Quatro MpCPs foram clonadas, expressas em sistema heterólogo e tiveram sua estrutura cristalográfica resolvida. Ensaios bioquímicos e biofísicos confirmaram que as MpCPs presentes em diferentes grupos filogenéticos apresentam capacidades distintas no tocante à interação com o açúcar N-acetilglicosamina e de formar agregados ordenados. Estudos funcionais indicaram que estas características estão potencialmente relacionadas ao bloqueio de resposta de defesa da planta e ao crescimento do fungo, respectivamente. Quanto às MpNEPs, somente a isoforma MpNEP2 foi detectada durante a Vassoura-de-Bruxa. A partir da estrutura cristalográfica dessa proteína e ensaios de mutação sítio-dirigida, foi identificado um hairpin hidrofóbico exposto ao solvente, possivelemte associado à ancoragem da MpNEP2 na membrana celular, o qual é tão importante quanto o sítio ativo da proteína para a atividade biológica da mesma / Abstract: Moniliophthora perniciosa is the causal agent of Witches' Broom Disease of cocoa and a major agroeconomic concern in Brazil and Latin America. In order to efficiently control this disease, it is crucial to understand the molecular basis underlying its progression. During the attack to the plant, a pathogen releases molecules to suppress or alter the regular defense response of the host. Results obtained from the genome sequencing of M. perniciosa lead to the identification putative virulence factors belonging to the Cerato-platanin protein family (MpCPs), and to the Necrosis- and Ethylene-inducing Proteins (MpNEPs). CPs are important to fungus-host interaction process, acting as toxins, defense response-inducing molecules or allergens. NEPs are toxin-like pore-forming proteins, which affect only dicot plants. This project aimed at the functional characterization of the MpCPs and MpNEPs, as well as understanding their importance for the Witches' Broom Disease progression. Twelve MpCP-coding genes were identified, and comprehensive transcriptome and phylogenetic analyses showed a correlation between MpCPs evolutionary clusters and their expression patterns throughout the disease. Four representative MpCPs had their crystal structure resolved. Biophysical and biochemical characterizations showed a correlation between the MpCP clusters, regarding sugar (N-acetylglucosamine) binding and protein self-assembling, which are possibly related to plant defense response suppression and hyphal growth, respectively. As for the MpNEPs, only the isoform MpNEP2 was shown to be expressed during the Whitches' Broom Disease. Its crystalloghaphic structure, along with site-directed mutagenesis and functional assays revealed that, besides the protein's active site, an hydrophobic hairpin exposed to te solvent is important to the necrosis-promoting activity, probably mediating the contact of MpNEP2 with the cell membrane / Mestrado / Genetica de Microorganismos / Mestre em Genética e Biologia Molecular

Proteinas - Estrutura

Relação planta-patógeno

Elicitores

Cerato-platanina

Proteína NEP

Proteins - Characterization

Plant-pathogen relationships

Elicitors

Cerato-platanin

NEP protein

Molecular characterization of elicitor-responsive genes in cotton

Phillips, Sonia Melanie

02 May 2012

D.Phil. / The fungus, Verticillium dahliae, is the causative agent of Verticillium wilt, which results in significant cotton (Gossypium hirsutum) crop losses worldwide. This study contributes to the elucidation of cotton defence responses against V. dahliae. The identification, cloning and characterization of three genes that were differentially expressed in response to elicitation with a cell wall-derived (CWD) V. dahliae elicitor are described. It was hypothesized that the molecular architectures of the three characterized genes are supportive of a role in cotton defence against V. dahliae. As one of these genes was present as two homoeologous copies, this study also reports on the molecular characterization of both homoeologs, thus providing further insight into the processes of genomic evolution between homoeologous loci in allotetraploid cotton. The three genes were initially represented as expressed sequence tags (ESTs), obtained from a previous differential display reverse transcription polymerase chain reaction (DDRT-PCR) study by Zwiegelaar (2003), as part of an MSc project. These ESTs, designated C1B10, C4B5 and C4B4, were differentially induced upon elicitation with a CWD V. dahliae elicitor (Zwiegelaar, 2003). In the present study, the genes represented by the three ESTs were identified and characterized by genome walking and 5‘/3‘ rapid amplification of cDNA ends (RACE). Additionally, PCR and reverse-transcription PCR (RT-PCR) were utilized, where necessary, to obtain internal sequences, not covered by the genome walking and RACE reactions. Through the use of these molecular techniques, the full transcript and genomic sequences of each of the three genes was obtained, including their promoters. The promoter of each gene was analyzed for cis-elements driving gene transcription, through bioinformatic analysis. Furthermore, the copy number of each gene was determined through Southern blot analysis. The genes were translated to reveal their encoded protein sequences. The amino acid sequences were submitted to a basic local alignment (BLAST) search of the NCBI database to identify, and align them with, homologous proteins from other plant species (and those from G. hirsutum, if any). An in silico analysis of the encoded protein of each gene was also performed. This examination included domain architecture, post-translational modification, subcellular location and tertiary structure predictions. This study also involved the isolation of the elicitor from the cell walls of V. dahliae fungal cultures. The potency of the freshly-isolated elicitor was investigated with a triphenyltetrazolium chloride (TTC) viability assay on cotton cell suspensions. Its potential to induce PR-proteins was also explored but these results were inconclusive. In addition, expression studies were performed with real-time PCR (q-PCR), to confirm the up- or down-regulation of each gene upon elicitation of cotton cell suspensions with the CWD V. dahliae elicitor, and to investigate the time frame/kinetics of induction. The gene corresponding to the C1B10 EST was designated GhLIPN as this study revealed that it encodes a lipin protein. Lipins are novel proteins with phosphatidate phosphatase 1 (PAP1) activity, exclusive to eukaryotes. They play a fundamental role in the lipid metabolism of organisms ranging in complexity from yeast to animals and plants. In plants, this role includes lipid membrane remodelling during phosphate (Pi) deficiency. During the study of the GhLIPN gene, it was discovered that it occurred as two distinct homoeologous copies from the A- and D-co-resident genomes of allopolyploid G. hirsutum. The GhLIPN homoeologs were named GhLIPN I and N for Insert present and No insert, respectively, based on the presence or absence of a 13 base pair (bp) insertion/deletion (indel) site in intron 6.

Cotton verticillium wilt

Gossypium hirsutum

Cotton diseases and pests

Verticillium dahliae

Cotton disease and pest resistance

Gene expression

Plant-pathogen relationships

Comparison between conventional and quantum dot labeling strategies for LPS binding studies in Arabidopsis thaliana

Mgcina, Londiwe Siphephise

09 December 2013

M.Sc. (Biochemistry) / Lipopolysaccharide (LPS) is a complex lipoglycan that is found in the outer membrane of Gram-negative bacteria and is composed of three regions namely the fatty acid Lipid A, a core region of short oligosaccharide chains and an O-antigen region of polysaccharides. When LPS is recognized as a microbe-/pathogen-associated molecular pattern (M/PAMP), it not only induces an innate immune response in plants but also stimulates the development of defence responses such as the immediate release of reactive oxygen species/intermediates (ROS/I), pathogen-related (PR) gene expression and activation of the hypersensitive response (HR), resulting in stronger subsequent pathogen interactions. The identification and characterisation of the elusive LPS receptor/receptor complex in plants is thus of importance, since understanding the mechanism of perception and specific signal transduction pathways will clarify, and lead to the advancement of, basal resistance in plants in order to decrease crop plant losses due to pathogen attack. In mammals, LPS binds to a LPS binding protein (LBP) to form a LPS-LBP complex which is translocated to myeloid differentiation 2 (MD2) with the presence/absence of its co-receptor, a glycosylphosphatidylinositol (GPI)-linked protein, CD14. The interaction occurs on the host membrane and triggers an inflammatory defence response through the signalling cascade activated by the interaction with Toll-like receptor 4 (TLR4). A similar LPS-receptor interaction is, however, unknown in plants. To address the LPS perception mechanism in plants, biological binding studies with regard to concentration, incubation time and temperature, affinity, specificity and saturation were conducted in Arabidopsis thaliana protoplasts using LPS labeled with Alexa 488 hydrazide. Quantum dots (Qdots), which allow non-covalent hydrophobic labeling of LPS, were further also employed in similar Arabidopsis protoplast binding studies. These studies were conducted by fluorescence determination through the use of a BD FACS Aria flow cytometer. Although Alexa-labeling does not affect the biological activity in mammalian studies, the same cannot necessarily be said for plant systems, and hence Qdots were included to address this question. The conjugation of Qdots to LPS was confirmed by transmission electron microscopy (TEM) and results illustrated higher fluorescence values as compared to Alexa-LPS fluorescence analysis. Furthermore, inhibition of the perception process is also reported using Wortmannin and Brefeldin A as suitable endo- and exocytosis inhibitors. Affinity, specificity and saturability as well as the role of endo- and exocytosis inhibition in LPS binding to protoplasts was ultimately demonstrated by both fluorophores, with the use of Qdots as a label proving to be a more sensitive strategy in comparison to the conventional Alexa 488 hydrazide label.

Plant-pathogen relationships

Plant defenses

Plant protoplasts

Binding sites (Biochemistry)

Gram-negative bacteria

Quantum dots

Interação planta-patógeno: análises químicas em Solanum pimpinellifolium L. e Solanum lycopersicum \'VFNT\' infectadas pelo tomato mottle mosaic virus / Plant-pathogen interaction: chemical analysis in Solanum pimpinellifolium L. and Solanum lycopersicum \'VFNT\' infected with tomato mottle mosaic virus

Alice Nagai

10 October 2017

As plantas se defendem do ataque de patógenos através de um sistema imune composto por duas fases. A primeira delas é mediada por receptores localizados na membrana celular ou intracelularmente, os quais são conhecidos como receptores de reconhecimento padrão (do inglês, pattern recognition receptors - PRR). Esses receptores reconhecem moléculas derivadas de microrganismos, as quais são conservadas evolutivamente e são chamadas de padrões moleculares associados a patógenos (do inglês, pathogen-associated molecular patterns - PAMPs). Esse reconhecimento dispara uma resposta de defesa conhecida como PTI (do inglês, PAMP-triggerd immunity - PTI). Alguns patógenos foram aptos a sintetizar moléculas capazes de suprimir a PTI e essas moléculas são denominadas de efetores. A resposta que ocorre devido à ação dos efetores é chamada de susceptibilidade disparada por efetores (do inglês, effector-triggered susceptibility - ETS). Entretanto, plantas resistentes podem reconhecer os efetores através de proteínas de resistência localizadas intracelularmente, ativando a imunidade disparada por efetores (do inglês, effector-triggeredimmunity - ETI). De modo geral, as respostas advindas da PTI e da ETI são similares, mas a segunda é ativada mais rapidamente e é mediada por um único gene de resistência R. Por essa razão, a ETI é conhecida como uma resposta à doença qualitativa e as plantas não desenvolvem sintomas, caracterizando a interação incompatível. Por outro lado, a PTI é mediada por diversos genes e as respostas de defesa são tardias, possibilitando a disseminação do patógeno pelas células da planta e a ocorrência da doença, o que caracteriza a interação compatível. Nas respostas de defesa, moléculas como o óxido nítrico, as poliaminas e o ácido salicílico participam do processo de sinalização. O sistema antioxidante da planta é ativado de modo a mitigar os efeitos das espécies reativas de oxigênio e o metabolismo da planta é alterado. Dessa maneira, o estudo das respostas de defesa contra patógenos, pode ser uma ferramenta útil para estabelecer controles efetivos para as doenças de plantas / Plants defend themselves from pathogen attack through an active immunity system composed by two phases. The first is mediated by cell surface and intracellular pattern recognition receptors (PRR), which recognizes conserved molecules derived from microbes known as pathogen-associated molecular patterns (PAMPs). This recognition triggers a defense response called PAMP-triggered immunity (PTI). Throughout evolution, pathogens were able to synthesize molecules capable of suppressing PTI. These molecules are named effectors and they are responsible for effector-triggered susceptibility (ETS). However, resistant plants can recognize effectors by intracellular resistance (R) proteins, initiating effector-triggered immunity (ETI). In general, responses derived from PTI and ETI are the same, but the latter is activated faster and is mediated by a single R gene. For this reason, ETI-response is also known as qualitative disease response (QDR) and plants do not develop disease symptoms, characterizing the incompatible interaction. On the other hand, PTI is mediated by several genes and the defense response is delayed, enabling the pathogen to spread out and to cause disease. This interaction is known as compatible. In defense responses, molecules like nitric oxide, polyamines and salicylic acid can participate in signaling process. The antioxidant system can be activated to quench the ROS effects and the plant metabolism is altered. In this sense, studying defense responses against pathogens can help to develop tools to establish effective control methods for plant disease

Antioxidantes não enzimáticos

Interação planta-patógeno

Metabolômica

Sinalizadores

Tomate

Metabolomics

Non-enzymatic antioxidants

Plant-pathogen interaction

Signaling molecules

Tomato

Predição in silico e caracterização parcial das bacteriocinas de Xylella fastidiosa / In silico prediction and partial characterization of the bacteriocins produced by Xylella fastidiosa

Duarte, Rodrigo Roberto Rafagnin

16 January 2013

Xylella fastidiosa é o agente causal de uma série de doenças que ocorrem em plantas economicamente importantes como laranjeiras, videiras e cafeeiros, causando no Estado de São Paulo prejuízos relevantes à indústria citrícola. Esta bactéria Gram-negativa é restrita ao xilema das plantas e à porção anterior do trato digestório dos insetos vetores das famílias Cicadellidae e Cercopidae, conhecidos como cigarrinhas. Tentativas de elucidar os mecanismos de virulência e patogenicidade adotados por esta bactéria apontam a formação do biofilme como etapa fundamental para o estabelecimento da infecção e o consequente desenvolvimento da doença na planta, mas fatores adicionais parecem contribuir, tais como a produção de toxinas. As bacteriocinas são proteínas com atividade antibiótica contra cepas próximas à espécie produtora e que já foram associadas à virulência e patogenicidade de outras bactérias. Uma varredura in silico no genoma de X. fastidiosa 9a5c revelou 13 sequências codificadoras de microcinas putativas no cromossomo. Transcritos de todos esses genes foram detectados por RT-qPCR em culturas de X. fastidiosa 9a5c, e análises comparativas com genomas públicos (cepas Temecula1, Dixon, Ann-1, M23, M12, EB92-1 e GB514) e recém sequenciados por nosso grupo de pesquisa (cepas U24d, J1a12, 3124, Hib4, Pr8x e Fb7) revelaram que cada cepa possui seu próprio arsenal de bacteriocinas. Diferenças encontradas in silico entre os loci de bacteriocinas nas cepas foram demonstradas experimentalmente. Nossos resultados comprovam a variabilidade predita nos quatro clusters de bacteriocinas que identificamos, o que é esperado para genes relacionados à adaptação e patogenicidade. Destes loci, três foram detectados por RT-PCR como transcritos policistrônicos. Nossa tentativa de detectar essas proteínas em culturas de X. fastidiosa (através de sequenciamento de polipeptídeos por HPLC-MS/MS) foi capaz de identificar uma das bacteriocinas putativas e, portanto, o conjunto de nossas observações apóia a continuidade dos estudos para elucidar o papel das bacteriocinas na fisiopatologia de X. fastidiosa. / Xylella fastidiosa is the causal agent of diseases that affect several economically important crops such as sweet orange trees, grapevines and coffee trees, causing in the State of São Paulo considerable losses mainly to the citrus industry. This Gram-negative bacterium is restricted to the plant xylem and to the upper gastrointestinal tract of its insect vectors, the sharpshooters from the Cicadellidae and Cercopidae families. Attempts to elucidate the virulence and pathogenicity pathways employed by this bacterium point the biofilm formation as a fundamental step for the establishment of the infection and the consequent development of the plant disease, but additional factors seem to contribute to these processes, such as the production of toxins. Bacteriocins are proteinaceous antibiotics that act against closely-related species and have been previously associated with virulence and pathogenicity in other bacteria. An in silico screening of the X. fastidiosa 9a5c genome revealed 13 coding sequences as putative microcins in the chromosome. Transcripts from all those genes were detected through RT-qPCR in X. fastidiosa 9a5c cultures, and comparative analyses on the public genomes (Temecula1, Dixon, Ann-1, M23, M12, EB92-1 and GB514) plus the ones recently sequenced by our group (U24d, J1a12, 3124, Hib4, Pr8x and Fb7) revealed that each strain possesses its own arsenal of bacteriocins. Differences found in silico among the loci in all strains were experimentally confirmed. Our results demonstrated the predicted variability in the four bacteriocins clusters as expected for adaptation and pathogenicity-related genes. Three out of the four bacteriocins loci were detected by RT-PCR as polycistronic transcripts. Our attempt to detect these proteins in X. fastidiosa cultures (using HPLC-MS/MS polypeptide sequencing) identified one of the putative bacteriocins, and therefore our observations warrant further efforts to elucidate the role of bacteriocins in the X. fastidiosa physiopathology.

Bacteriocinas

Bacteriocins

Citrus variegated chlorosis

Clorose variegada do citros

Doença de Pierce

Fitopatógenos

Microcinas

Microcins

Pierce's disease

Plant pathogen

Epidemiology and impacts of a leaf spot disease in Veratrum viride (Melanthiaceae)

Sutton, Leeah R, Levy, Foster

01 May 2022

Fungal phytopathogens can cause disease epidemics in crops, weeds, andpopulations of native plants. To investigate the impact of a foliar phytopathogen on the native herbaceous species, Veratrum viride, a demographic and disease assessment was carried out on two high elevation grassy bald populations on Roan Mountain, Tennessee. A leaf spot disease impacted all plants in both populations, causing widespread premature senescence of leaves and stems. Disease severity increased over the course of the growing season. Based on host disease symptoms and fungal conidia morphology, Pseudocercosporella sublineolata was shown to be the causal pathogen. A study of herbarium specimens showed no evidence that the disease was epidemic in the species and no evidence of an increase in disease prevalence over time. However, the disease was more common in the mid Atlantic and southern Appalachian regions, but rare in New England.

climate change

disease severity

plant pathogen

Pseudocercosporella sublineolata

Roan Mountain

temporal

Biology

Ecology and Evolutionary Biology

Plant Pathology

Effet de la sélection fluctuante sur le pathogène du blé Zymoseptoria tritici par une approche d'évolution expérimentale / Effect of fluctuating selection on the wheat pathogen Zymoseptoria tritici using an experimental evolution approach

Jallet, Arthur

23 October 2019

Un défi important en Biologie est de comprendre comment les organismes s’adaptent à des environnements fluctuants et de déterminer l’importance relative de la plasticité phénotypique et des mutations dans cette adaptation. Nous avons examiné la réponse d’un pathogène du blé (Zymoseptoria tritici) aux fluctuations de température grâce à des approches de transcriptomique, de phénotypage (fitness relative et pathogénie) et de génomique. Pour cela, une évolution expérimentale a été menée in vitro à partir de deux clones ayant évolué dans trois régimes thermiques : à 17°C, à 23°C et en température fluctuante. Le niveau d’expression de 11% du génome a évolué de manière distincte entre les deux génotypes fondateurs en conditions de fluctuations. Nous avons également observé une plus forte densité de gènes différentiellement exprimés dans des régions connues pour être riches en éléments transposables. L’évolution en conditions fluctuantes a favorisé la robustesse du transcriptome. La fitness relative estimée dans les conditions d’évolution a augmenté uniquement pour les lignées fluctuantes issues d’un des deux génotypes fondateurs. La différence de croissance entre les deux ancêtres en conditions de fluctuations et leur différent niveau de plasticité d’expression pourraient expliquer ces résultats différents. Enfin, nous avons observé : i). des pertes de pathogénie in planta suite à l’évolution à 17°C et en fluctuations, ii). aucune perte de chromosomes accessoires, iii). de nombreuses mutations dans le génome, dont des mutations codantes dans des effecteurs. Ces travaux apportent de nombreux éléments de compréhension des mécanismes évolutifs et moléculaires sous-jacents à l’évolution de Z. tritici dans des environnements variables. / An important challenge in Biology is to understand how organisms adapt to fluctuating environments and to determine the relative significance of phenotypic plasticity and mutations in this adaptation. We examined the response of a wheat pathogen (Zymoseptoria tritici) to temperature fluctuations using transcriptomics, phenotyping (relative fitness and disease level) and genomics. With this goal, we conducted an in vitro experimental evolution from two Z. tritici clones that evolved in three thermal conditions: at 17°C, at 23°C and under temperature fluctuations. Expression level of 11% of the genome evolved in a different way between the two founder genotypes that evolved under fluctuating conditions. We also observed a higher density of differentially expressed genes in regions known to be enriched in transposable elements. Evolution under fluctuating selection promoted robustness of the transcriptome. The relative fitness estimated in the same conditions as for the experimental evolution did increase for fluctuating lineages only for one of the founder genotypes. The difference of growth between the two ancestors in fluctuating conditions and their distinct level of expression plasticity could explain these opposite results. Finally we observed: i). in planta pathogenicity losses for lineages evolved at 17°C or under fluctuations ii). no accessory chromosome loss, iii). many de novo mutations, including coding mutations in effector genes. This work contributes to shade light on the evolutionary and molecular mechanisms underlying the evolution of Z. tritici in variable environments.

Expression de gènes

Fitness relative

Fluctuation

Mutation

Phytopathogène

Plasticité phénotypique

Fluctuation

Gene expression

Mutation

Phenotypic plasticity

Plant pathogen

Relative fitness

Battle Tactics: Ralstonia solanacearum K60 type III effector impacts plant cytoskeleton

Rachel Rose Marie Hiles (15353779)

26 April 2023

<p> The plant cytoskeleton is commonly considered a vital component of cell growth and development; however, it also plays a critical role in plant immunity. During plant immunity, the cytoskeleton orchestrates rapid and precise immune-associated processes. For instance, the cytoskeleton mobilizes and orients the movement of organelles, proteins, and chemical signaling. To counter plant immunity, bacterial pathogens deliver virulence proteins, known as T3Es (type III effectors), into plant cells through a needle-like apparatus called the type III secretion system (T3SS). A novel T3E, called RipU, interacts with the cytoskeleton. Data has shown that RipU co-localizes with cytoskeletal markers in tobacco leaves. Ectopic expression of RipU can suppress PTI responses like ROS bursts or seedling growth inhibition. Tomato plants inoculated with <em>Rs</em> K60 lacking RipU showed less wilting and root colonization, suggesting that RipU plays a role in pathogenesis and virulence. Furthermore, inducible expression of RipU in Arabidopsis dramatically alters plant development. These plants have wavy roots, branching root hairs, and underdeveloped true leaves. Our results suggest that by targeting the cytoskeleton, RipU contributes to <em>Rs</em> K60s pathogenicity and virulence. </p>

Plant cell and molecular biology

Plant pathology

Plant Pathogen Ralstonia solanacear...

Type III effectors

Cytoskeleton

Localization

confocal microscopy assay