Project description:Many of the genes coding for secreted protein effectors are arranged in gene clusters in the genome of the biotrophic plant pathogen Ustilago maydis. The largest of these gene clusters, cluster 19A, encodes 24 secreted effectors. Deletion of the entire cluster results in severe attenuation of virulence. The generation and analysis strains carrying sub-deletions identified 9 genes significantly contributing to tumor formation after seedling infection. As the individual contributions of these genes to tumor formation were small, we studied the response of maize plants to the whole cluster mutant as well as to several individual mutants by array analysis. This revealed distinct plant responses, demonstrating that the respective effectors have discrete plant targets. Many of the genes coding for secreted protein effectors are arranged in gene clusters in the genome of the biotrophic plant pathogen Ustilago maydis. The largest of these gene clusters, cluster 19A, encodes 24 secreted effectors. Deletion of the entire cluster results in severe attenuation of virulence. The generation and analysis strains carrying sub-deletions identified 9 genes significantly contributing to tumor formation after seedling infection. As the individual contributions of these genes to tumor formation were small, we studied the response of maize plants to the whole cluster mutant as well as to several individual mutants by array analysis. This revealed distinct plant responses, demonstrating that the respective effectors have discrete plant targets. We used the Affymetrix maize genome array to analyze the transcriptional responses of maize to cluster 19A mutants and individual sub-deletions for the cluster 19A genes tin1, tin3, tin4 and tin5. We found plant responses to the mutants were significantly different although the macroscopic phenotypes of the individual mutants were very similar. U. maydis infected parts of maize seedling leaves were dissected 4 days after inoculation with strain SG200∆19A, SG200∆tin1, SG200∆tin3, SG200∆tin4 and SG200∆tin5, respectively. We previously submitted data of maize leaves that were treated with the progenitor wild type strain SG200 as well as mock-infections under identical experimetal conditions (GEO: GSE10023). These data served as controls for this experiment.

Project description:Ustilago maydis is a basidiomycete fungus that causes smut disease in maize. Most prominent symptoms of the disease are plant tumors, which can be induced by U. maydis on all aerial parts of the plant. We identified two linked genes, pit1 and pit2, which are specifically expressed during plant colonization. Deletion mutants for either pit1 or pit2 are unable to induce tumor development and elicit plant defense responses. We used the Affymetrix maize genome array to analyze the transcriptional responses of maize to deletion pit1 and pit2 mutants and found plant responses to both mutants being not significantly distinguishable. U. maydis infected parts of maize seedling leaves were dissected 4 days after inoculation with strain SG200Dpit1 and SG200Dpit2, respectively. We previously submitted data of maize leaves that were treated with the progenitor wild type strain SG200 as well as mock-infections under identical experimetal conditions (GEO: GSE10023, 4d mock and 4d SG200 Samples, equivalent record in Arrayexpress: E-GEOD-10023). These data served as controls for this experiment.

Project description:The fungal pathogen Ustilago maydis establishes a biotrophic relationship with its host plant maize. Hallmarks of the disease are large plant tumors in which fungal proliferation occurs. Plants have developed various defense pathways to cope with pathogens. We used microarrays to detail the global programme of gene expression during the infection process of Ustilago maydis in its host plant to get insights into the defense programs and the metabolic reprogramming needed to supply the fungus with nutrients. Experiment Overall Design: In three independent experiments plants were infected with the solopathogenic U. maydis strain SG200. Samples from infected leaves were taken at 12 and 24 hours post infection, as well as 2, 4 and 8 days post infection. Samples from uninfected control plants were taken at the same time points.

Project description:The basidiomycete Ustilago maydis causes smut disease in maize. Colonization of the host plant is initiated by direct penetration of cuticle and cell wall of maize epidermis cells. The invading hyphae are surrounded by the plant plasma membrane and proliferate within the plant tissue. We identified a novel secreted protein, termed Pep1. Disruption mutants of pep1 are not affected in saprophytic growth and develop normal infection structures. However, Δpep1 mutants fail to penetrate the epidermal cell wall and elicit a strong plant defense response. Using Affymetrix maize arrays we identified about 110 plant genes which are differentially regulated in Δpep1 and wild type infections during the penetration stage. Experiment Overall Design: In three independent experiments plants were infected with the strain SG200Dpep1 which is derived from the solopathogenic U. maydis strain SG200. Samples from infected leaves were taken at 24 hours post infection. Samples were treated under the same conditions as described previosly (Doehlemann et al. (2008) Plant J, in press).

Project description:Anthocyanin induction in plant is considered a general defense response against biotic and abiotic stresses. The infection by Ustilago maydis, the corn smut pathogen, is accompanied with anthocyanin induction in leaf tissue. We revealed that anthocyanin is intentionally induced by the virulence promoting secreted effector protein Tin2. Tin2 protein functions inside plant cells where it interacts with cytoplasmic maize protein kinase ZmTTK1. Tin2 masks an ubiquitin-proteasome degradation motif in ZmTTK1 leading to a more stable active kinase. Active ZmTTK1 controls transcriptional activation of genes in the anthocyanin biosynthesis pathway rerouting phenylalanine away from lignin biosynthesis. Therefore, we performed microarray analysis to understand how maize gene transcription in phenylpropanoid pathway is differentially changed after infection with Ustilago maydis SG200 (wild type) and SG200Dtin2 (anthocyanin-inducing effector mutant).

Project description:Ustilago maydis is a plant-pathogenic fungus that establishes a biotrophic relationship with its host Zea mays. The biotrophic interaction is initiated upon host penetration, and involves expansion of the host plasma membrane around hyphae, which is thought to facilitate the exchange of nutrients and virulence factors. Transcriptional regulators involved in the establishment of an infectious dikaryon and penetration into the host have been identified, however, regulators involved in the post-penetration stages remained to be elucidated. In the study we report the identification of an Ustilago maydis forkhead transcription factor, Fox1, which is exclusively expressed during biotrophic development. Deletion of fox1 results in reduced virulence and impaired tumour development in planta. Microarray analyses of Δfox1-infected plant tissue identified Fox1 as a transcriptional activator, involved in the expression of secreted effectors required for virulence. Maize plants were infected with a mixture of either FB1 and FB2 (wild-type), or FB1∆fox1 and FB2∆fox1 crossings, to measure the impact of fox1 on pathogenic development. Early Golden Bantam maize plants were grown in a phytochamber in a 15h/9h light-dark cycle; light period started/ended with 1h ramping of light intensity. Maize plants were kept at 28°C (light) and 20° (dark). Plantlets were individually sown in pots with potting soil (Fruhstorfer Pikiererde) and infected 7 days after sowing, 1 h before end of the light period. Infected leaf tumor material from at least 10 plants was collected 5 days post infection, 1 h before the end of the light period and directly frozen in liquid nitrogen for RNA-extraction. RNA samples were extracted from infected leaf tissue 5 days after infection.

Project description:In fungi, sexual compatibility is controlled by mating type loci that prevent self-fertilization. In the plant pathogenic fungus Ustilago maydis, the b mating type locus encodes a pair of unrelated homeodomain proteins, termed bE and bW. After fusion of two compatible, haploid cells, the bE and bW proteins form a heterodimeric complex, but only if they are derived from different, compatible alleles. The active bE/bW complex is required and sufficient to initiate pathogenic development of U. maydis, which is prerequisite for sexual reproduction of the fungus. However, the role of the b heterodimer during later stages of pathogenic development was unclear. To analyze b function during in planta development, we generated a temperature-sensitive bE allele (bEts) encoding a protein with a single amino acid alteration at the border of the homeodomain. This mutation leads to a stop in pathogenic development at the restrictive temperature in planta, while bEts strains show normal development at permissive temperature. At restrictive temperature, hyphae develop enlarged, bulbous cells at their tips that contain multiple nuclei, indicating a severe defect in cell division. DNA array analysis of bEts mutant strains in planta revealed a b-dependent regulation of genes coding for secreted proteins that were shown to influence fungal virulence. Our data demonstrate that in U. maydis the b heterodimer is not only essential to establish the heterodikaryon after mating of two compatible sporidia and to initiate fungal pathogenicity, but also to sustain in planta proliferation and ensure sexual reproduction. Maize plants were infected with a mixture of either FB1 and FB2 (wild-type), or RAb1ts and RAb2ts (temperature-sensitive b heterodimer) and kept at 22°C (permissive conditions). Control samples of FB1/FB2 and RAb1ts and RAb2ts were taken 5 days post inoculation at 22 °C (1 replicate each), to see if strains expressing the bts heterodimer show wildtype-like biotrophic development. To measure the impact of the b heterodimer on pathogenic development, infected plants were shifted for 9 hours to resrictive conditions (31°C) 111 hours post infection. After the temperature shift FB1/FB2 (3 replicates) infections developed normal, whereas RAb1ts/RAb2ts (3 replicates) infections were not able to further proliferate in planta because of a none-functional b heterodimer.

Project description:In this study, RNA-seq based comparative transcriptome analysis was used to study the genetic response of maize silk to pollen tube penetration and in comparison to the fungal invasion of Fusarium graminearum and Ustilago maydis. RNA-seq libraries of 8 tissues were generated from leaf, root, seed, pollen tube, silk, pollinated silk, infected silk with Fusarium and infected silk with Ustilago.

Project description:Zea mays transcriptome profiling of infected seedlings by the Ustilago maydis wildtype and the seedling specific effector mutant demonstrated the variation of gene expression in the mutant and the classes of genes that are absent in the mutant as compared to the wildtype U. maydis SG200 strain. Two dye competitive hybridizations were performed on Agilent Oligo arrays. Comparison were done 1) with mock and infected samples at 6dpi. 2) between the two 6dpi infected samples with wildtype and the secreted effector mutant

Project description:Ustilago maydis causes common smut in maize, which is characterized by tumor formation in aerial parts of maize. Tumor comes from the de novo cell division of highly developed bundle sheath and subsequent cell enlargement. However, its mechanism is still unknown. Here, we characterize the U. maydis effector Sts2 (Small tumor on seedlings 2), which promotes the division of hyperplasia tumor cells. Upon infection, Sts2 is translocated into maize cell nucleus, where it acts as a transcriptional activator, and the transactivation activity is crucial for its virulence function. Sts2 interacts with ZmNECAP1, a yet undescribed plant transcriptional activator, and it activates the expression of several leaf developmental regulators to potentiate tumor formation. Contrary, a suppressive Sts2-SRDX inhibits the tumor formation by SG200 in a dominant negative way, underpinning the central role of Sts2 for tumorigenesis. Our results not only disclosed the virulence mechanism of a tumorigenic effector, but also revealed the essential role of leaf developmental regulators in pathogen-induced tumor formation.