AI Article Synopsis
- Ectomycorrhiza formation allows soil fungi to take carbohydrates from host plants, but details about sugar transporters in certain fungi remain unclear.
- Data from the Tuber melanosporum genome revealed 23 potential hexose transporters, with three (Tmelhxt1, Tmel2281, Tmel131) selected for further study based on their expression patterns.
- Tmelhxt1 and Tmel2281 were shown to facilitate growth in sugars when expressed in yeast, indicating they function as high-affinity transporters at the plant-fungus interface, while Tmel131 may play a different role related to alternative carbon sources in fruiting bodies.
Article Abstract
In a natural forest ecosystem, ectomycorrhiza formation is a way for soil fungi to obtain carbohydrates from their host plants. However, our knowledge of sugar transporters in ectomycorrhizal ascomycetous fungi is limited. To bridge this gap we used data obtained from the sequenced genome of the ectomycorrhizal fungus Tuber melanosporum Vittad. to search for sugar transporters. Twenty-three potential hexose transporters were found, and three of them (Tmelhxt1, Tmel2281 and Tmel131), differentially expressed during the fungus life cycle, were investigated. The heterologous expression of Tmelhxt1 and Tmel2281 in an hxt-null Saccharomyces cerevisiae strain restores the growth in glucose and fructose. The functional characterization and expression profiles of Tmelhxt1 and Tmel2281 in the symbiotic phase suggest that they are high affinity hexose transporters at the plant-fungus interface. On the contrary, Tmel131 is preferentially expressed in the fruiting body and its inability to restore the S. cerevisiae mutant strain growth led us to hypothesize that it could be involved in the transport of alternative carbon sources important for a hypothetical saprophytic strategy for the complete maturation of the carpophore.
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| http://dx.doi.org/10.1016/j.fgb.2015.05.006 | DOI Listing |
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