Spore germination of Trichoderma atroviride is inhibited by its LysM protein TAL6.

LysM motifs are carbohydrate-binding modules found in prokaryotes and eukaryotes. They have general N-acetylglucosamine binding properties and therefore bind to chitin and related carbohydrates. In plants, plasma-membrane-bound proteins containing LysM motifs are involved in plant defence responses, but also in symbiotic interactions between plants and microorganisms. Filamentous fungi secrete LysM proteins that contain several LysM motifs but no enzymatic modules. In plant pathogenic fungi, for LysM proteins roles in dampening of plant defence responses and protection from plant chitinases were shown. In this study, the carbohydrate-binding specificities and biological function of the LysM protein TAL6 from the plant-beneficial fungus Trichoderma atroviride were investigated. TAL6 contains seven LysM motifs and the sequences of its LysM motifs are very different from other fungal LysM proteins investigated so far. The results showed that TAL6 bound to some forms of polymeric chitin, but not to chito-oligosaccharides. Further, no binding to fungal cell wall preparations was detected. Despite these rather weak carbohydrate-binding properties, a strong inhibitory effect of TAL6 on spore germination was found. TAL6 was shown to specifically inhibit germination of Trichoderma spp., but interestingly not of other fungi. Thus, this protein is involved in self-signalling processes during fungal growth rather than fungal-plant interactions. These data expand the functional repertoire of fungal LysM proteins beyond effectors in plant defence responses and show that fungal LysM proteins are also involved in the self-regulation of fungal growth and development.

Self-assembly at air/water interfaces and carbohydrate binding properties of the small secreted protein EPL1 from the fungus Trichoderma atroviride.

The protein EPL1 from the fungus Trichoderma atroviride belongs to the cerato-platanin protein family. These proteins occur only in filamentous fungi and are associated with the induction of defense responses in plants and allergic reactions in humans. However, fungi with other lifestyles also express cerato-platanin proteins, and the primary function of this protein family has not yet been elucidated. In this study, we investigated the biochemical properties of the cerato-platanin protein EPL1 from T. atroviride. Our results showed that EPL1 readily self-assembles at air/water interfaces and forms protein layers that can be redissolved in water. These properties are reminiscent of hydrophobins, which are amphiphilic fungal proteins that accumulate at interfaces. Atomic force microscopy imaging showed that EPL1 assembles into irregular meshwork-like substructures. Furthermore, surface activity measurements with EPL1 revealed that, in contrast to hydrophobins, EPL1 increases the polarity of aqueous solutions and surfaces. In addition, EPL1 was found to bind to various forms of polymeric chitin. The T. atroviride genome contains three epl genes. epl1 was predominantly expressed during hyphal growth, whereas epl2 was mainly expressed during spore formation, suggesting that the respective proteins are involved in different biological processes. For epl3, no gene expression was detected under most growth conditions. Single and double gene knock-out strains of epl1 and epl2 did not reveal a detectable phenotype, showing that these proteins are not essential for fungal growth and development despite their abundant expression.

Fungal chitinases: diversity, mechanistic properties and biotechnological potential.

Chitin derivatives, chitosan and substituted chito-oligosaccharides have a wide spectrum of applications ranging from medicine to cosmetics and dietary supplements. With advancing knowledge about the substrate-binding properties of chitinases, enzyme-based production of these biotechnologically relevant sugars from biological resources is becoming increasingly interesting. Fungi have high numbers of glycoside hydrolase family 18 chitinases with different substrate-binding site architectures. As presented in this review, the large diversity of fungal chitinases is an interesting starting point for protein engineering. In this review, recent data about the architecture of the substrate-binding clefts of fungal chitinases, in connection with their hydrolytic and transglycolytic abilities, and the development of chitinase inhibitors are summarized. Furthermore, the biological functions of chitinases, chitin and chitosan utilization by fungi, and the effects of these aspects on biotechnological applications, including protein overexpression and autolysis during industrial processes, are discussed in this review.