 |
|
Tearing down the fungal cell wall
December 05, 2006Fungal gene impacts viability of destructive pathogen
Blacksburg, Va. - Scientists at the Virginia Bioinformatics Institute and Duke University Medical Center have pinpointed a fungal gene that appears to play an important role in the development and virulence of Alternaria brassicicola. A. brassicicola, a destructive fungal pathogen that causes black spot disease on most cultivated Brassica crops worldwide, results in considerable leaf loss in many economically important crops including canola, cabbage and broccoli. Sensitivity to spores of Alternaria species is also clinically associated with human respiratory disorders such as allergy, asthma, and chronic sinusitis.
Spores, which are often termed conidia in some fungi, are an essential part of the developmental cycle of A. brassicicola and arise from the branching filaments or hyphae that make up the fungus. In the study, the investigators show that disruption of the AbNPS2 gene drastically impacts the integrity of the cell wall of fungal spores produced in the reproductive phase of A. brassicicola's life cycle. The AbNPS2 gene most likely directs the synthesis of a molecule that plays an essential role in maintaining the structure of the cell wall of the conidia.
Associate Professor Christopher Lawrence of the Virginia Bioinformatics Institute and the Department of Biological Sciences at Virginia Tech, director of the study, remarked: "Typical A. brassicicola spores are hydrophobic. Water droplets placed on a lawn of fungal hyphae bearing normal spores are repelled and easily roll off the surface. When the AbNPS2 gene is disrupted, the linkage of the outermost layer of the fungal spore cell wall to the middle layer appears to be disturbed, destroying the cell wall's regular architecture and making the spores permeable to water. This has drastic effects on the viability of the spores."
Kwang-Hyung Kim, doctoral student and the lead author on the paper, stated: "What we have been able to show is that mutation of the AbNPS2 gene is accompanied by structural changes that occur in the cell wall of the spores, a decrease in spore germination rate, lower survival rates for the spores under adverse environmental conditions, and a reduced ability of the fungus to damage the host plant. These observations may open up a route to develop new and innovative research strategies aimed at understanding the host-pathogen interaction for this destructive plant pathogen."
The investigators used a wide range of experimental approaches to look in detail at the link between the function of the gene and its impact on the structure of the spore cell wall. A recently developed gene disruption method was used to generate the fungal mutants (See "New method enables gene disruption in destructive fungal pathogen" at www.vbi.vt.edu/article/articleview/538/1/15/). Bioinformatic and gene prediction tools were applied to probe the structure and organization of the AbNPS2 gene and the surrounding region in the recently sequenced A. brassicicola genome, a collaborative project nearing completion with Washington University Genome Sequencing Center in St. Louis. Electron microscopy revealed some of the dramatic structural changes in the cell wall arising from disruption of the gene.
Dr. Nancy Keller, Professor in the Department of Plant Pathology at the University of Wisconsin, Madison and international expert in fungal secondary metabolism, commented: "The finding that a non-ribosomal peptide synthetase is integral to conidial morphology further illustrates the versatile and essential role of these secondary metabolites in fungal biology. For years long ignored, the function of natural products is rapidly becoming one of the hot topics in fungal biology; the findings reported in this study by Dr. Lawrence's research group further underline their importance."
The AbNPS2 gene encodes a large protein known as a non-ribosomal peptide synthetase. This protein directs the synthesis of secondary metabolites known as non-ribosomal peptides. However, the functions of many of these proteins and the subsequent synthesized metabolites are largely unknown. Dr. Lawrence added: "To the best of our knowledge, this is the first report that a fungal non-ribosomal peptide synthetase is associated with cell wall construction in fungal spores. The putative secondary metabolite produced by the protein encoded by this gene could serve as a physical bridge in the layers of the cell wall or function as a regulator of cell wall biosynthesis. Future work will focus on identifying the role of the product of the AbNPS2 gene which should allow us to get an important handle on the precise series of molecular events that give rise to these drastic effects on spore viability."
Virginia Tech
Associate Professor Christopher Lawrence of the Virginia Bioinformatics Institute and the Department of Biological Sciences at Virginia Tech, director of the study, remarked: "Typical A. brassicicola spores are hydrophobic. Water droplets placed on a lawn of fungal hyphae bearing normal spores are repelled and easily roll off the surface. When the AbNPS2 gene is disrupted, the linkage of the outermost layer of the fungal spore cell wall to the middle layer appears to be disturbed, destroying the cell wall's regular architecture and making the spores permeable to water. This has drastic effects on the viability of the spores."
Kwang-Hyung Kim, doctoral student and the lead author on the paper, stated: "What we have been able to show is that mutation of the AbNPS2 gene is accompanied by structural changes that occur in the cell wall of the spores, a decrease in spore germination rate, lower survival rates for the spores under adverse environmental conditions, and a reduced ability of the fungus to damage the host plant. These observations may open up a route to develop new and innovative research strategies aimed at understanding the host-pathogen interaction for this destructive plant pathogen."
The investigators used a wide range of experimental approaches to look in detail at the link between the function of the gene and its impact on the structure of the spore cell wall. A recently developed gene disruption method was used to generate the fungal mutants (See "New method enables gene disruption in destructive fungal pathogen" at www.vbi.vt.edu/article/articleview/538/1/15/). Bioinformatic and gene prediction tools were applied to probe the structure and organization of the AbNPS2 gene and the surrounding region in the recently sequenced A. brassicicola genome, a collaborative project nearing completion with Washington University Genome Sequencing Center in St. Louis. Electron microscopy revealed some of the dramatic structural changes in the cell wall arising from disruption of the gene.
Dr. Nancy Keller, Professor in the Department of Plant Pathology at the University of Wisconsin, Madison and international expert in fungal secondary metabolism, commented: "The finding that a non-ribosomal peptide synthetase is integral to conidial morphology further illustrates the versatile and essential role of these secondary metabolites in fungal biology. For years long ignored, the function of natural products is rapidly becoming one of the hot topics in fungal biology; the findings reported in this study by Dr. Lawrence's research group further underline their importance."
The AbNPS2 gene encodes a large protein known as a non-ribosomal peptide synthetase. This protein directs the synthesis of secondary metabolites known as non-ribosomal peptides. However, the functions of many of these proteins and the subsequent synthesized metabolites are largely unknown. Dr. Lawrence added: "To the best of our knowledge, this is the first report that a fungal non-ribosomal peptide synthetase is associated with cell wall construction in fungal spores. The putative secondary metabolite produced by the protein encoded by this gene could serve as a physical bridge in the layers of the cell wall or function as a regulator of cell wall biosynthesis. Future work will focus on identifying the role of the product of the AbNPS2 gene which should allow us to get an important handle on the precise series of molecular events that give rise to these drastic effects on spore viability."
Virginia Tech
How Candida albicans transforms from its normally benign form into life-threatening form
Researchers at the Agency for Science, Technology and Research's (A*STAR) Institute of Molecular and Cell Biology (IMCB) have discovered new molecular mechanisms that provide a more detailed understanding of how the normally benign Dr. Jekyll-like fungus known as Candida albicans transforms into a serious and often life-threatening Mr. Hyde-like form.
White blood cells are picky about sugar
Biology textbooks are blunt-neutrophils are mindless killers. These white blood cells patrol the body and guard against infection by bacteria and fungi, identifying and destroying any invaders that cross their path.
New compound effectively treats fungal infections
A new mechanism to attack hard-to-treat fungal infections has been revealed by scientists from the biotech company Anacor Pharmaceuticals Inc., California, and the European Molecular Biology Laboratory [EMBL] outstation in Grenoble, France.
Scientists develop fungus-fighting vaccine
group of scientists in Italy have developed a vaccine with the potential to protect against fungal pathogens that commonly infect humans, according to a study by Torosantucci and colleagues in the September 5 issue of The Journal of Experimental Medicine.
Deadly infectious entity of prions discovered
The mysterious, highly infectious prions, which cause the severe destruction of the brain that characterizes "mad cow disease" and several human brain degenerative disorders, can be rendered harmless in the laboratory by a slight alternation of the three-dimensional conformation or shape of the prion protein's structure.
More Fungal Cell News Articles
 | The Molecular and Cellular Biology of the Yeast Saccharomyces: Cell Cycle and Cell Biology (Monograph 21c) In all eukaryotic cells, each fundamental process cycle progression and its control, protein secretion and targeting, transcription and its regulation, mRNA processing, and DNA replication accomplished by essentially identical cellular machinery composed of essentially identical protein components. This conservation of function has catapulted the yeasts Saccharomyces cerevisiae and... |
 | Fungal Morphogenesis (Developmental and Cell Biology Series) by David Moore Fungal Morphogenesis brings together in one book, for the first time, the full scope of fungal developmental biology. The book provides a coherent account of the subject and puts forward ideas that can provide a basis for future research. Throughout, the author blends together physiological, biochemical, structural and molecular descriptions within an evolutionary framework. Sufficient... |
| Cell Biology of Plant and Fungal Tip Growth (Nato: Life and Behavioural Sciences, 328) Tip growth is a type of cellular growth that is represented in many and diverse cell types, which are important to plant breeding (pollen tubes), agriculture (root hairs) and plant and animal pathology (fungal hyphae). Also moss and fern protonemata as well as algal zygotes and yeasts exhibit the features unique for tip growth: directable apical linear growth which renders the cell able to... | |
| Biochemistry of Cell Walls and Membranes in Fungi by P. J. Kuhn | |
 | The Mycota: A Comprehensive Treatise on Fungi as Experimental Systems for Basic and Applied Research, Volume VIII: Biology of the Fungal Cell Biology of the Fungal Cell offers a select sampling of current knowledge and direction of fundamental research into the cellular structure, morphogenesis and development of fungi. Topics range from the mechanisms of invasive growth and controls of polarity, to the nature of extracellular matrices and the various connections through the cell wall to the cytoskeleton and beyond. The fungal cell is... |
 | The role of glomalin, a protein produced by arbuscular mycorrhizal fungi, in sequestering potentially toxic elements [An article from: Environmental Pollution] by M.C. Gonzalez-Chavez, R. Carrillo-Gonzalez, Wright This digital document is a journal article from Environmental Pollution, published by Elsevier in 2004. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.Description: Naturally occurring soil organic compounds stabilize potentially toxic elements (PTEs) such as Cu, Cd, Pb, and Mn. The... |
 | Fungal Cell Wall: Structure, Synthesis, and Assembly by Jose Ruiz-Herrera Fungal Cell Wall presents a comprehensive examination of the structure, synthesis, and growth of the fungal cell wall and explores the reasons for the cell wall's importance to the survival of fungi. Topics covered include the composition and structure of the fungal cell wall and how they are affected by endogenous and external factors; the structure and synthesis of glucans, chitin, and... |
 | The Molecular and Cellular Biology of Yeast Saccharamyces: Cell Cycle and Cell Biology (Cold Spring Harbor Monograph Series) Univ. of North Carolina, Chapel Hill. Focus on progress made in the study of yeast molecular and cellular biology. Numerous contributors. Softcover not published... |
| Tip Growth in Plant and Fungal Cells | |
 | The Yeast Nucleus (Frontiers in Molecular Biology) This book is concerned with the various nuclear activities of two yeasts: Saccharomyces cerevisiae and Schizosaccharomyces pombe. Both are excellent models for higher eukaryotes, including... |
| © 2008 BrightSurf.com |