Phytopathogenic and mycorrhizal fungi often penetrate living hosts by using appressoria and related structures. The differentiation of similar structures in saprotrophic fungi to penetrate dead plant biomass has seldom been investigated and has been reported only in the model fungus Podospora anserina. Here, we report on the ability of many saprotrophs from a large range of taxa to produce appressoria on cellophane. Most Ascomycota and Basidiomycota were able to form appressoria. In contrast, none of the three investigated Mucoromycotina was able to differentiate such structures. The ability of filamentous fungi to differentiate appressoria no longer belongs solely to pathogenic or mutualistic fungi, and this raises the question of the evolutionary origin of the appressorium in Eumycetes.
The regulation of ascospore germination in filamentous fungi has been poorly investigated so far. To unravel new genes involved in this regulation pathway, we conducted a genetic screen in
Podospora anserina
, and we isolated 57 mutants affected in ascospore germination.
In Podospora anserina as in many other ascomycetes, ascospore germination is a regulated process that requires breaking of dormancy. Despite its importance in survival and dispersal, ascospore germination in filamentous fungi has been poorly investigated and little is known about its regulation and genetic control. We have designed a positive genetic screen that led to the isolation of mutants showing uncontrolled germination, the GUN mutants. In this paper, we report on the characterization of GUN1SG. We show that GUN1SG is mutated in Pa_6_1340, the ortholog of Magnaporthe oryzae Pth2, which encodes a Carnitine-acetyltransferase (CAT) involved in the shuttling of acetyl-CoA between peroxisomes and mitochondria and which is required for appressorium-development. Bioinformatic analysis revealed that the mutated residue (I441) is highly conserved among the Fungi, and that the mutation has a deleterious impact on the protein function. We show that GUN1 is essential for ascospore germination and that the protein is localized both in mitochondria and in peroxisomes. Finally, epistasis studies allowed us to place GUN1 upstream of the PaMpk2 MAPK pathway and the PaNox2/PaPls1 complex in the regulation of ascospore germination. The identification of GUN1, the ortholog of Pth2, in ascospore germination, strengthens the idea of a common genetic regulation governing both appressorium development and melanized ascospore germination. In addition, we characterize the second CAT encoded in P. anserina genome, Pa_3_7660/GUP1, and we show that the function of both CATs is conserved in P. anserina.
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