Gene expression profiling during conidiation in the rice blast pathogen Magnaporthe oryzae

Conidiation of phytopathogenic fungi is a key developmental process that plays a central role in their life cycles and in epidemics. However, there is little information on conidiation-induced molecular changes in the rice blast fungus Magnaporthe oryzae. As a first step to understand conidiogenesis...

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Veröffentlicht in:	PloS one 2012-08, Vol.7 (8), p.e43202
Hauptverfasser:	Kim, Kyoung Su, Lee, Yong-Hwan
Format:	Artikel
Sprache:	eng
Schlagworte:	Agricultural biotechnology Agriculture Aspergillus nidulans Biology Biosynthesis Cell walls Clonal deletion Crop diseases Culture Techniques Deletion mutant DNA microarrays Epidemics Fungal Proteins - genetics Fungi Gene expression Genes Genetic aspects Genetic engineering Genetic transcription Genomes Genomics Hydrophobic surfaces Infections Kinases Life cycles Magnaporthe - genetics Magnaporthe - growth & development Magnaporthe - physiology Magnaporthe grisea Magnaporthe oryzae Metabolism Morphology Mutagenesis Neurospora crassa Oligonucleotide Array Sequence Analysis Oligonucleotides Oryza - microbiology Pathogenesis Physiological aspects Phytopathogenic fungi Proteins Reproduction, Asexual - genetics Rice Rice blast Rice blast disease Sequence Deletion Spores, Fungal - genetics Spores, Fungal - physiology Transcription factors Transcriptome
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description	Conidiation of phytopathogenic fungi is a key developmental process that plays a central role in their life cycles and in epidemics. However, there is little information on conidiation-induced molecular changes in the rice blast fungus Magnaporthe oryzae. As a first step to understand conidiogenesis in this fungus, we measured genome-wide gene expression profiles during conidiation using a whole genome oligonucleotide microarray. At a two-fold expression difference, approximately 4.42% and 4.08% of genes were upregulated and downregulated, respectively, during conidiation. The differentially expressed genes were functionally categorized by gene ontology (GO) term analysis, which demonstrated that the gene set encoded proteins that function in metabolism, cell wall biosynthesis, transcription, and molecule transport. To define the events of the complicated process of conidiogenesis, another set of microarray experiments was performed using a deletion mutant for MoHOX2, a stage-specific transcriptional regulator essential for conidial formation, which was expressed de novo in a conidiation-specific manner in M. oryzae. Gene expression profiles were compared between the wild-type and the ΔMohox2 mutant during conidiation. This analysis defined a common gene set that was upregulated in the wild-type and downregulated in the ΔMohox2 mutant during conidiation; this gene set is expected to include conidiation-related downstream genes of MoHOX2. We identified several hundred genes that are differentially-expressed during conidiation; our results serve as an important resource for understanding the conidiation, a process in M. oryzae, which is critical for disease development.
doi_str_mv	10.1371/journal.pone.0043202
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However, there is little information on conidiation-induced molecular changes in the rice blast fungus Magnaporthe oryzae. As a first step to understand conidiogenesis in this fungus, we measured genome-wide gene expression profiles during conidiation using a whole genome oligonucleotide microarray. At a two-fold expression difference, approximately 4.42% and 4.08% of genes were upregulated and downregulated, respectively, during conidiation. The differentially expressed genes were functionally categorized by gene ontology (GO) term analysis, which demonstrated that the gene set encoded proteins that function in metabolism, cell wall biosynthesis, transcription, and molecule transport. To define the events of the complicated process of conidiogenesis, another set of microarray experiments was performed using a deletion mutant for MoHOX2, a stage-specific transcriptional regulator essential for conidial formation, which was expressed de novo in a conidiation-specific manner in M. oryzae. Gene expression profiles were compared between the wild-type and the ΔMohox2 mutant during conidiation. This analysis defined a common gene set that was upregulated in the wild-type and downregulated in the ΔMohox2 mutant during conidiation; this gene set is expected to include conidiation-related downstream genes of MoHOX2. 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However, there is little information on conidiation-induced molecular changes in the rice blast fungus Magnaporthe oryzae. As a first step to understand conidiogenesis in this fungus, we measured genome-wide gene expression profiles during conidiation using a whole genome oligonucleotide microarray. At a two-fold expression difference, approximately 4.42% and 4.08% of genes were upregulated and downregulated, respectively, during conidiation. The differentially expressed genes were functionally categorized by gene ontology (GO) term analysis, which demonstrated that the gene set encoded proteins that function in metabolism, cell wall biosynthesis, transcription, and molecule transport. 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subjects	Agricultural biotechnology Agriculture Aspergillus nidulans Biology Biosynthesis Cell walls Clonal deletion Crop diseases Culture Techniques Deletion mutant DNA microarrays Epidemics Fungal Proteins - genetics Fungi Gene expression Genes Genetic aspects Genetic engineering Genetic transcription Genomes Genomics Hydrophobic surfaces Infections Kinases Life cycles Magnaporthe - genetics Magnaporthe - growth & development Magnaporthe - physiology Magnaporthe grisea Magnaporthe oryzae Metabolism Morphology Mutagenesis Neurospora crassa Oligonucleotide Array Sequence Analysis Oligonucleotides Oryza - microbiology Pathogenesis Physiological aspects Phytopathogenic fungi Proteins Reproduction, Asexual - genetics Rice Rice blast Rice blast disease Sequence Deletion Spores, Fungal - genetics Spores, Fungal - physiology Transcription factors Transcriptome
title	Gene expression profiling during conidiation in the rice blast pathogen Magnaporthe oryzae
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