Plant colonization by the vascular wilt fungus Fusarium oxysporum requires FOW1, a gene encoding a mitochondrial protein

The soil-borne fungus Fusarium oxysporum causes vascular wilts of a wide variety of plant species by directly penetrating roots and colonizing the vascular tissue. The pathogenicity mutant B60 of the melon wilt pathogen F. oxysporum f. sp. melonis was isolated previously by restriction enzyme-mediated DNA integration mutagenesis. Molecular analysis of B60 identified the affected gene, designated FOW1, which encodes a protein with strong similarity to mitochondrial carrier proteins of yeast. Although the FOW1 insertional mutant and gene-targeted mutants showed normal growth and conidiation in culture, they showed markedly reduced virulence as a result of a defect in the ability to colonize the plant tissue. Mitochondrial import of Fow1 was verified using strains expressing the Fow1-green fluorescent protein fusion proteins. The FOW1-targeted mutants of the tomato wilt pathogen F. oxysporum f. sp. lycopersici also showed reduced virulence. These data strongly suggest that FOW1 encodes a mitochondrial carrier protein that is required specifically for colonization in the plant tissue by F. oxysporum.     

Class V chitin synthase determines pathogenesis in the vascular wilt fungus Fusarium oxysporum and mediates resistance to plant defence compounds

Chitin, a beta-1,4-linked polysaccharide of N-acetylglucosamine, is a major structural component of fungal cell walls. Fungi have multiple classes of chitin synthases that catalyse N-acetylglucosamine polymerization. Here, we demonstrate the requirement for a class V chitin synthase during host infection by the vascular wilt pathogen Fusarium oxysporum. The chsV gene was identified in an insertional mutagenesis screen for pathogenicity mutants. ChsV has a putative myosin motor and a chitin synthase domain characteristic of class V chitin synthases. The chsV insertional mutant and a gene replacement mutant of F. oxysporum display morphological abnormalities such as hyphal swellings that are indicative of alterations in cell wall structure and can be partially restored by osmotic stabilizer. The mutants are unable to infect and colonize tomato plants or to grow invasively on tomato fruit tissue. They are also hypersensitive to plant antimicrobial defence compounds such as the tomato phytoanticipin alpha-tomatine or H2O2. Reintroduction of a functional chsV copy into the mutant restored the growth phenotype of the wild-type strain. These data suggest that F. oxysporum requires a specific class V chitin synthase for pathogenesis, most probably to protect itself against plant defence mechanisms.     

Two xylanase genes of the vascular wilt pathogen Fusarium oxysporum are differentially expressed during infection of tomato plants

Two genes encoding putative family F xylanases from the tomato vascular wilt pathogen Fusarium oxysporum f.sp. lycopersici have been cloned and sequenced. The two genes, designated xyl2 and xyl3, encode proteins with calculated molecular masses of 33 and 39.3?kDa and isoelectric points of 8.9 and 6.7, respectively. The predicted amino acid sequences show significant homology to other family F xylanases. XYL3 contains a cellulose-binding domain in its N-terminal region. Southern analysis suggested that xyl2 and xyl3 homologs are also present in other formae speciales of F. oxysporum. Both genes were expressed during growth on oat spelt xylan and tomato vascular tissue in vitro. RT-PCR revealed that xyl3 is expressed in roots and in the lower stems of tomato plants infected by F. oxysporum f.sp. lycopersici throughout the whole disease cycle, whereas xyl2 is only expressed during the final stages of disease.     

Biotransformation of 2,4,6-trinitrotoluene (TNT) by the fungus Fusarium oxysporum

The fungus Fusarium oxysporum was isolated and identified from the aquatic plant M. aquaticum. The capability of this fungus to transform 2,4,6-trinitrotoluene (TNT) in liquid cultures was investigated TNT was added to shake flask cultures and transformed into 2-amino-4,6-dinitrotoluene (2-A-DNT), 4-amino-2,6-dinitrotoluene (4-A-DNT), and 2,4-diamino-6-nitrotoluene (2,4-DAT) via 2- and 4-hydroxylamino-dinitrotoluene derivatives, which could be detected as intermediate metabolites. Transformation of TNT, 2-A-DNT, and 4-A-DNT was observed by whole cultures and with isolated mycelium. Cell-free protein extracts from the extracellular, soluble, and membrane-bound fractions were prepared from this fungus and tested for TNT-reducing activity. The concentrated extracellular culture medium was unable to transform TNT; however, low levels of TNT transformation were observed by the membrane fraction in the presence of nicotinamide adenine dinucleotide phosphate in an argon atmosphere. A concentrated extract of soluble enzymes also transformed TNT, but to a lesser extent. When TNT toxicity was studied with this fungus, a 50% decrease in the growth of F. oxysporum mycelium was observed when exposed to 20 mg/L TNT.     

GsZFP1, a new Cys2/His2-type zinc-finger protein, is a positive regulator of plant tolerance to cold and drought stress

Plant acclimation to environmental stress is controlled by a complex network of regulatory genes that compose distinct stress-response regulons. The C2H2-type zinc-finger proteins (ZFPs) have been implicated in different cellular processes involved in plant development and stress responses. Through microarray analysis, an alkaline (NaHCO(3))-responsive ZFP gene GsZFP1 was identified and subsequently cloned from Glyycine soja. GsZFP1 encodes a 35.14?kDa protein with one C2H2-type zinc-finger motif. The QALGGH domain, conserved in most plant C2H2-type ZFPs, is absent in the GsZFP1 protein sequence. A subcellular localization study using a GFP fusion protein indicated that GsZFP1 is localized to the nucleus. Real-time RT-PCR analysis showed that GsZFP1 was induced in the leaf by ABA (100?μM), salt (200?mM NaCl), and cold (4°C), and in the root by ABA (100?μM), cold (4°C), and drought (30% PEG 6000). Over-expression of GsZFP1 in transgenic Arabidopsis resulted in a greater tolerance to cold and drought stress, a decreased water loss rate, and an increase in proline irrespective of environmental conditions. The over-expression of GsZFP1 also increased the expression of a number of stress-response marker genes, including CBF1, CBF2, CBF3, NCED3, COR47, and RD29A in response to cold stress and RAB18, NCED3, P5CS, RD22, and RD29A in response to drought stress, especially early during stress treatments. Our studies suggest that GsZFP1 plays a crucial role in the plant response to cold and drought stress.