Your search keyword '"Roland Marmeisse"' showing total 2 results

1. A Fungal Conserved Gene from the Basidiomycete Hebeloma cylindrosporum Is Essential for Efficient Ectomycorrhiza Formation

Author

Jeanne Doré, Roland Marmeisse, Jean-Philippe Combier, and Gilles Gay

Subjects

Microbiology, QR1-502, Botany, QK1-989

Abstract

We used Agrobacterium-mediated insertional mutagenesis to identify genes in the ectomycorrhizal fungus Hebeloma cylindrosporum that are essential for efficient mycorrhiza formation. One of the mutants presented a dramatically reduced ability to form ectomycorrhizas when grown in the presence of Pinus pinaster. It failed to form mycorrhizas in the presence of glucose at 0.5 g liter–1, a condition favorable for mycorrhiza formation by the wild-type strain. However, it formed few mycorrhizas when glucose was replaced by fructose or when glucose concentration was increased to 1 g liter–1. Scanning electron microscopy examination of these mycorrhizas revealed that this mutant was unable to differentiate true fungal sheath and Hartig net. Molecular analyses showed that the single-copy disrupting T-DNA was integrated 6,884 bp downstream from the start codon, of an open reading frame potentially encoding a 3,096-amino-acid-long protein. This gene, which we named HcMycE1, has orthologs in numerous fungi as well as different other eukaryotic microorganisms. RNAi inactivation of HcMycE1 in the wild-type strain also led to a mycorrhizal defect, demonstrating that the nonmycorrhizal phenotype of the mutant was due to mutagenic T-DNA integration in HcMycE1. In the wild-type strain colonizing P. pinaster roots, HcMycE1 was transiently upregulated before symbiotic structure differentiation. Together with the inability of the mutant to differentiate these structures, this suggests that HcMycE1 plays a crucial role upstream of the fungal sheath and Hartig net differentiation. This study provides the first characterization of a fungal mutant altered in mycorrhizal ability.

Published

2014

2. Nonmycorrhizal (Myc¯) Mutants of Hebeloma cylindrosporum Obtained Through Insertional Mutagenesis

Author

Jean-Philippe Combier, Delphine Melayah, Colette Raffier, Régis Pépin, Roland Marmeisse, and Gilles Gay

Subjects

Microbiology, QR1-502, Botany, QK1-989

Abstract

Polyethylene glycol-mediated transformation of protoplasts was used as a method for insertional mutagenesis to obtain mutants of the ectomycorrhizal fungus Hebeloma cylindrosporum impaired in symbiotic ability. Following restriction enzyme-mediated integration or conventional plasmid insertion, a library of 1,725 hygromycin-resistant monokaryotic transformants was generated and screened for the symbiotic defect, using Pinus pinaster seedlings as host plants. A total of 51 transformants displaying a dramatically reduced mycorrhizal ability were identified. Among them, 29 were nonmycorrhizal (myc¯), but only 10 of them had integrated one or several copies of the transforming plasmid in their genome. Light and scanning electron microscopy observations of pine roots inoculated with myc¯ mutants suggested that we selected mutants blocked at early stages of interaction between partners or at the stage of Hartig net formation. Myc¯ mutants with plasmid insertions were crossed with a compatible wild-type monokaryon and allowed to fruit. Monokaryotic progenies were obtained in three independent crosses and were analyzed for symbiotic activity and plasmid insertion. In all three progenies, a 1:1 myc¯:myc+ segregation ratio was observed, suggesting that each myc¯ phenotype resulted from a single gene mutation. However, for none of the three mutants, the myc¯ phenotype segregated with any of the plasmid insertions. Our results support the idea that master genes, the products of which are essential for symbiosis establishment, do exist in ectomycorrhizal fungi.

Published

2004