Abstract
Transcription factors (TFs) play critical roles in the control of development and pathogenicity of phytopathogens by directly or indirectly regulating the expression of downstream genes. Here, we identified and characterized a zinc finger TF UvMsn2 in Ustilaginoidea virens, a homolog of MoMsn2 from the rice blast fungus. Heterogenous complementation assay revealed that UvMsn2 fully restored the defects of the ∆Momsn2 mutant in vegetative growth, conidiation and pathogenicity. Deletion of UvMsn2 in U. virens led to a reduction of the pathogen in vegetative growth, aerial hyphae and conidiation. Additionally, the ∆Uvmsn2 mutant displayed defects in conidial morphology and germination, as well as mitochondrial morphology. Pathogenicity and toxicity assays revealed that the ∆Uvmsn2 mutant was non-pathogenic and less inhibitory to rice seed germination. The ∆Uvmsn2 mutant showed different sensitivity to various stresses. Further microscopic examination found that UvMsn2 was localized in both cytosol and nucleus, and translocated from cytosol to nucleus under the treatment of NaCl. Our results demonstrate that UvMsn2 is a critical TF that regulates the vegetative growth, conidiogenesis, stress response, mitochondrial morphology and virulence in the rice false smut fungus.
Highlights
Eukaryotes have evolved complex and precise mechanisms for perception and transduction of extracellular signals to adapt to environmental stresses, including transcriptional regulation of genes (Rajvanshi et al 2017)
Our results demonstrate that UvMsn2 plays important roles in vegetative growth, conidiogenesis, stress response, mitochondrial morphology and pathogenicity in U. virens
UvMsn2 is a homolog of MoMsn2 from the rice blast fungus M. oryzae Our previous study revealed that MoMsn2, a transcription factor from M. oryzae, plays pleotropic roles in hyphal growth, conidiogenesis, stress response, mitochondrial morphology and pathogenicity of M. oryzae by modulating the expression of a series of genes directly or indirectly (Zhang et al 2014)
Summary
Eukaryotes have evolved complex and precise mechanisms for perception and transduction of extracellular signals to adapt to environmental stresses, including transcriptional regulation of genes (Rajvanshi et al 2017). Under glucose-rich conditions or in cells at the log phase of growth, Msn is distributed in the cytosol, but is translocated from the cytosol to the nucleus under stress or glucose depletion conditions (Gorner et al 2002). Msn shows a carbon source-dependent localization pattern and plays a role in fatty acid oxidation in yeast (Rajvanshi et al 2017). Msn targets several β-oxidation genes that are involved in fatty acid oxidation to regulate fatty acid metabolism (Rajvanshi et al 2017). Msn2/4 plays a role in targeting the rapamycin (TOR) pathway by which to regulate multiple cellular processes in response to nutrients (Crespo and Hall 2002). Msn is required for multi-stress responses, conidiation and virulence (Liu et al 2013)
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