The role of cellular morphogenesis in the pathogenicity of the rice blast fungus Magnaporthe oryzae

Appressorium-mediated plant infection is a common strategy used by many plant pathogenic fungi. Understanding the underlying genetic network that controls cellular differentiation of appressorium is therefore pivotal to design durable resistance strategies for these devastating pathogens. This thesis describes four published studies, which investigate the role of septin GTPases in infection and the role of secretion during plant tissue invasion by the rice blast pathogen Magnaporthe oryzae. Appressorium development involves a series of morphogenetic changes that are tightly regulated by cell cycle checkpoints. Entry into mitosis allows differentiation of an appressorium, while penetration peg emergence appears to require progression through subsequent cell cycle checkpoints and cytokinesis. The studies presented here show that symmetry-breaking events that occur during appressorium differentiation are mediated by scaffold proteins, named septins. Septin GTPases recruit actomyosin ring components during septation and define the site of cytokinesis. They also recruit a toroidal cortical F-actin network to the appressorium pore that provides cortical rigidity to facilitate plant infection. Septins act as diffusion barriers for proteins that mediate membrane curvature necessary for penetration peg formation. Repolarization of the F-actin cytoskeleton at the appressorium pore is essential for plant penetration and is controlled by cell polarity regulators, such as Cdc42 and Chm1. Septin-mediated plant infection is regulated by NADPH oxidase (Nox) dependent generation of reactive oxygen species (ROS). The Nox2/NoxR complex is essential for septin organization at the appressorium pore. Septins are therefore key determinants of appressorium repolarization. I also report an investigation of fungal secretory processes during tissue invasion and present evidence that distinct pathways are involved in effector secretion by Magnaporthe oryzae. A BrefeldinA-sensitive pathway is necessary for secretion of apoplastic effectors, such as Bas4 and Slp1, while a BrefeldinA-insensitive pathway is necessary for secretion of effectors destined for delivery to rice cells.The Halpin Scholarship for Rice Blast Researc

Comparative analysis of plant immune receptor architectures uncovers host proteins likely targeted by pathogens.

BACKGROUND: Plants deploy immune receptors to detect pathogen-derived molecules and initiate defense responses. Intracellular plant immune receptors called nucleotide-binding leucine-rich repeat (NLR) proteins contain a central nucleotide-binding (NB) domain followed by a series of leucine-rich repeats (LRRs), and are key initiators of plant defense responses. However, recent studies demonstrated that NLRs with non-canonical domain architectures play an important role in plant immunity. These composite immune receptors are thought to arise from fusions between NLRs and additional domains that serve as "baits" for the pathogen-derived effector proteins, thus enabling pathogen recognition. Several names have been proposed to describe these proteins, including "integrated decoys" and "integrated sensors". We adopt and argue for "integrated domains" or NLR-IDs, which describes the product of the fusion without assigning a universal mode of action. RESULTS: We have scanned available plant genome sequences for the full spectrum of NLR-IDs to evaluate the diversity of integrations of potential sensor/decoy domains across flowering plants, including 19 crop species. We manually curated wheat and brassicas and experimentally validated a subset of NLR-IDs in wild and cultivated wheat varieties. We have examined NLR fusions that occur in multiple plant families and identified that some domains show re-occurring integration across lineages. Domains fused to NLRs overlap with previously identified pathogen targets confirming that they act as baits for the pathogen. While some of the integrated domains have been previously implicated in disease resistance, others provide new targets for engineering durable resistance to plant pathogens. CONCLUSIONS: We have built a robust reproducible pipeline for detecting variable domain architectures in plant immune receptors across species. We hypothesize that NLR-IDs that we revealed provide clues to the host proteins targeted by pathogens, and that this information can be deployed to discover new sources of disease resistance

Studies on Peroxisome Motility in the Model Fungal System Ustilago maydis

Peroxisomes are ubiquitous organelles found in almost all eukaryotes. They are sensitive to changes in cellular homeostasis and involved in various metabolic processes. Deficiencies in peroxisome function cause severe neurological problems. Here I report, investigation of peroxisome motility and its relation to peroxisomal functions in the fungal model system Ustilago maydis. Peroxisomes are mostly motile in Ustilago maydis. Motile peroxisomes show different motility patterns: short-range pulse type movements and long range bidirectional motility. Motility behaviour is not static as oscillating peroxisomes may start long-range motility. Here, I present evidence that long-range bidirectional peroxisome motility is an energy driven process and is essential for homogeneous distribution of peroxisomes. Similar to early endosomes and endoplasmic reticulum, microtubule motors kinesin-3 and dynein are responsible for long-range peroxisome transport. In addition to using the same molecular motors for transport, early endosomes, endoplasmic reticulum and peroxisomes have the same transport velocity. Interestingly, motile peroxisomes and endoplasmic reticulum tubules co-localize with early endosomes. Functional investigation of early endosome mutants, Δrab5a and Yup1ts has revealed a novel transport mechanism where endoplasmic reticulum and peroxisomes hitch hike on early endosomes. Additionally, I report functional characterization of an AAA-ATPase, um05592, which has high homology to human protein NP_055873. Altogether these results reveal molecular mechanism of peroxisome transport in Ustilago maydis. Similarities in transport machinery illustrate Ustilago maydis as a model system to study peroxisome function in mammalian cells

Interfiber interactions alter the stiffness of gels formed by supramolecular self-assembled nanofibers

Cataloged from PDF version of article.Molecular self-assembly is a powerful technique for developing novel nanostructures by using noncovalent interactions such as hydrogen bonding, hydrophobic, electrostatic, metal-ligand, p-p and van der Waals interactions. These interactions are highly dynamic and are often delicate due to their relatively weak nature. However, a sufficient number of these weak interactions can yield a stable assembly. In this work, we studied the mechanical properties of self-assembled peptide amphiphile nanostructures in the nanometre and micrometre scale. Hydrogen bonding, hydrophobic and electrostatic interactions promote self-assembly of peptide amphiphile molecules into nanofibers. Bundles of nanofibers form a three-dimensional network resulting in gel formation. The effect of the nanofiber network on the mechanical properties of the gels was analyzed by AFM, rheology and CD. Concentration and temperature dependent measurements of gel stiffness suggest that the mechanical properties of the gels are determined by a number of factors including the interfiber interactions and mechanical properties of individual nanofibers. We point out that the divergence in gel stiffness may arise from the difference in strength of interfiber bonds based on an energetic model of elastic rod networks, along with continuum mechanical models of bundles of rods. This finding differs from the results observed with traditional polymeric materials. Understanding the mechanisms behind the viscoelastic properties of the gels formed by self-assembling molecules can lead to development of new materials with controlled stiffness. Tissue engineering applications can especially benefit from these materials, where the mechanical properties of the extracellular matrix are crucial for cell fate determination. © The Royal Society of Chemistry 2011

Nanomechanical characterization by double-pass force-distance mapping

Cataloged from PDF version of article.We demonstrate high speed force–distance mapping using a double-pass scheme. The topography is measured in tapping mode in the first pass and this information is used in the second pass to move the tip over the sample. In the second pass, the cantilever dither signal is turned off and the sample is vibrated. Rapid (few kHz frequency) force–distance curves can be recorded with small peak interaction force, and can be processed into an image. Such a double-pass measurement eliminates the need for feedback during force–distance measurements. The method is demonstrated on self-assembled peptidic nanofibers

Peroxisomes, lipid droplets, and endoplasmic reticulum "hitchhike" on motile early endosomes

This is the final version of the article. Available from the publisher via the DOI in this record.Intracellular transport is mediated by molecular motors that bind cargo to be transported along the cytoskeleton. Here, we report, for the first time, that peroxisomes (POs), lipid droplets (LDs), and the endoplasmic reticulum (ER) rely on early endosomes (EEs) for intracellular movement in a fungal model system. We show that POs undergo kinesin-3- and dynein-dependent transport along microtubules. Surprisingly, kinesin-3 does not colocalize with POs. Instead, the motor moves EEs that drag the POs through the cell. PO motility is abolished when EE motility is blocked in various mutants. Most LD and ER motility also depends on EE motility, whereas mitochondria move independently of EEs. Covisualization studies show that EE-mediated ER motility is not required for PO or LD movement, suggesting that the organelles interact with EEs independently. In the absence of EE motility, POs and LDs cluster at the growing tip, whereas ER is partially retracted to subapical regions. Collectively, our results show that moving EEs interact transiently with other organelles, thereby mediating their directed transport and distribution in the cell.This work was supported by the Portuguese Foundation for Science and Technology and FEDER/COMPETE (SFRH/BD/73532/2010 to S.C. Guimaraes) and CRUP/Treaty of Windsor (ACÇÕES INTEGRAD AS 2009, B-33/09 to G. Steinberg and M. Schuster). G. Steinberg acknowledges support from the Biotechnology and Biological Sciences Research Counc

The glycogen synthase kinase MoGsk1, regulated by Mps1 MAP kinase, is required for fungal development and pathogenicity in Magnaporthe oryzae

Magnaporthe oryzae, the causal agent of blast disease, is one of the most destructive plant pathogens, causing significant yield losses on staple crops such as rice and wheat. The fungus infects plants with a specialized cell called an appressorium, whose development is tightly regulated by MAPK signaling pathways following the activation of upstream sensors in response to environmental stimuli. Here, we show the expression of the Glycogen synthase kinase 3 (GSK3) MoGSK1 in M. oryzae is regulated by Mps1 MAP kinase, particularly under the stressed conditions. Thus, MoGSK1 is functionally characterized in this study. MoGsk1 is functionally homologues to the Saccharomyces cerevisiae GSK3 homolog MCK1. Gene replacement of MoGSK1 caused significant delay in mycelial growth, complete loss of conidiation and inability to penetrate the host surface by mycelia-formed appressorium-like structures, consequently resulting in loss of pathogenicity. However, the developmental and pathogenic defects of Delta mogsk1 are recovered via the heterologous expression of Fusarium graminearum GSK3 homolog gene FGK3, whose coding products also shows the similar cytoplasmic localization as MoGsk1 does in M. oryzae. By contrast, overexpression of MoGSK1 produced deformed appressoria in M. oryzae. In summary, our results suggest that MoGsk1, as a highly conservative signal modulator, dictates growth, conidiation and pathogenicity of M. oryzae

NADPH oxidases regulate septin-mediated cytoskeletal remodeling during plant infection by the rice blast fungus

notes: PMCID: PMC3581893types: Journal Article; Research Support, Non-U.S. Gov'tThe rice blast fungus Magnaporthe oryzae infects plants with a specialized cell called an appressorium, which uses turgor to drive a rigid penetration peg through the rice leaf cuticle. Here, we show that NADPH oxidases (Nox) are necessary for septin-mediated reorientation of the F-actin cytoskeleton to facilitate cuticle rupture and plant cell invasion. We report that the Nox2-NoxR complex spatially organizes a heteroligomeric septin ring at the appressorium pore, required for assembly of a toroidal F-actin network at the point of penetration peg emergence. Maintenance of the cortical F-actin network during plant infection independently requires Nox1, a second NADPH oxidase, which is necessary for penetration hypha elongation. Organization of F-actin in appressoria is disrupted by application of antioxidants, whereas latrunculin-mediated depolymerization of appressorial F-actin is competitively inhibited by reactive oxygen species, providing evidence that regulated synthesis of reactive oxygen species by fungal NADPH oxidases directly controls septin and F-actin dynamics.Biotechnology and Biological Sciences Research Council (BBSRC)National Natural Science Foundation of ChinaHalpin ScholarshipEuropean Research Council Advanced Investigator Awar

Interfiber interactions alter the stiffness of gels formed by supramolecular self-assembled nanofibers

Molecular self-assembly is a powerful technique for developing novel nanostructures by using noncovalent interactions such as hydrogen bonding, hydrophobic, electrostatic, metal-ligand, p-p and van der Waals interactions. These interactions are highly dynamic and are often delicate due to their relatively weak nature. However, a sufficient number of these weak interactions can yield a stable assembly. In this work, we studied the mechanical properties of self-assembled peptide amphiphile nanostructures in the nanometre and micrometre scale. Hydrogen bonding, hydrophobic and electrostatic interactions promote self-assembly of peptide amphiphile molecules into nanofibers. Bundles of nanofibers form a three-dimensional network resulting in gel formation. The effect of the nanofiber network on the mechanical properties of the gels was analyzed by AFM, rheology and CD. Concentration and temperature dependent measurements of gel stiffness suggest that the mechanical properties of the gels are determined by a number of factors including the interfiber interactions and mechanical properties of individual nanofibers. We point out that the divergence in gel stiffness may arise from the difference in strength of interfiber bonds based on an energetic model of elastic rod networks, along with continuum mechanical models of bundles of rods. This finding differs from the results observed with traditional polymeric materials. Understanding the mechanisms behind the viscoelastic properties of the gels formed by self-assembling molecules can lead to development of new materials with controlled stiffness. Tissue engineering applications can especially benefit from these materials, where the mechanical properties of the extracellular matrix are crucial for cell fate determination. © The Royal Society of Chemistry 2011