Characterization of an antifungal ß-1,3-glucanase from Ficus microcarpa latex and comparison of plant and bacterial ß-1,3-glucanases for fungal cell wall ß-glucan degradation.

MAIN CONCLUSION: Each ß-1,3-glucanase with antifungal activity or yeast lytic activity hydrolyzes different structures of ß-1,3-glucans in the fungal cell wall, respectively. Plants express several glycoside hydrolases that target chitin and ß-glucan in fungal cell walls and inhibit pathogenic fungal infection. An antifungal ß-1,3-glucanase was purified from gazyumaru (Ficus microcarpa) latex, designated as GlxGluA, and the corresponding gene was cloned and expressed in Escherichia coli. The sequence shows that GlxGluA belongs to glycoside hydrolase family 17 (GH17). To investigate how GlxGluA acts to degrade fungal cell wall ß-glucan, it was compared with ß-1,3-glucanase with different substrate specificities. We obtained recombinant ß-1,3-glucanase (designated as CcGluA), which belongs to GH64, from the bacterium Cellulosimicrobium cellulans. GlxGluA inhibited the growth of the filamentous fungus Trichoderma viride but was unable to lyse the yeast Saccharomyces cerevisiae. In contrast, CcGluA lysed yeast cells but had a negligible inhibitory effect on the growth of filamentous fungi. GlxGluA degraded the cell wall of T. viride better than CcGluA, whereas CcGluA degraded the cell wall of S. cerevisiae more efficiently than GlxGluA. These results suggest that the target substrates in fungal cell walls differ between GlxGluA (GH17 class I ß-1,3-glucanase) and CcGluA (GH64 ß-1,3-glucanase).

Structural Analysis and Construction of a Thermostable Antifungal Chitinase.

Chitin is a biopolymer of N-acetyl-d-glucosamine with ß-1,4-bond and is the main component of arthropod exoskeletons and the cell walls of many fungi. Chitinase (EC 3.2.1.14) is an enzyme that hydrolyzes the ß-1,4-bond in chitin and degrades chitin into oligomers. It has been found in a wide range of organisms. Chitinase from Gazyumaru (Ficus microcarpa) latex exhibits antifungal activity by degrading chitin in the cell wall of fungi and is expected to be used in medical and agricultural fields. However, the enzyme's thermostability is an important factor; chitinase is not thermostable enough to maintain its activity under the actual application conditions. In addition to the fact that thermostable chitinases exhibiting antifungal activity can be used under various conditions, they have some advantages for the production process and long-term preservation, which are highly demanded in industrial use. We solved the crystal structure of chitinase to explore the target sites to improve its thermostability. We rationally introduced proline residues, a disulfide bond, and salt bridges in the chitinase using protein-engineering methods based on the crystal structure and sequence alignment among other chitinases. As a result, we successfully constructed the thermostable mutant chitinases rationally with high antifungal and specific activities. The results provide a useful strategy to enhance the thermostability of this enzyme family. IMPORTANCE We solved the crystal structure of the chitinase from Gazyumaru (Ficus microcarpa) latex exhibiting antifungal activity. Furthermore, we demonstrated that the thermostable mutant enzyme with a melting temperature (Tm) 6.9°C higher than wild type (WT) and a half-life at 60°C that is 15 times longer than WT was constructed through 10 amino acid substitutions, including 5 proline residues substitutions, making disulfide bonding, and building a salt bridge network in the enzyme. These mutations do not affect its high antifungal activity and chitinase activity, and the principle for the construction of the thermostable chitinase was well explained by its crystal structure. Our results provide a useful strategy to enhance the thermostability of this enzyme family and to use the thermostable mutant as a seed for antifungal agents for practical use.

cDNA cloning, expression, and antifungal activity of chitinase from Ficus microcarpa latex: difference in antifungal action of chitinase with and without chitin-binding domain.

MAIN CONCLUSION: A chitin-binding domain could contribute to the antifungal ability of chitinase through its affinity to the fungal lateral wall by hydrophobic interactions. Complementary DNA encoding the antifungal chitinase of gazyumaru (Ficus microcarpa), designated GlxChiB, was cloned and expressed in Escherichia coli cells. The results of cDNA cloning showed that the precursor of GlxChiB has an N-terminal endoplasmic reticulum targeting signal and C-terminal vacuolar targeting signal, whereas mature GlxChiB is composed of an N-terminal carbohydrate-binding module family-18 domain (CBM18) and a C-terminal glycoside hydrolase family-19 domain (GH19) with a short linker. To clarify the role of the CBM18 domain in the antifungal activity of chitinase, the recombinant GlxChiB (wild type) and its catalytic domain (CatD) were used in quantitative antifungal assays under different ionic strengths and microscopic observations against the fungus Trichoderma viride. The antifungal activity of the wild type was stronger than that of CatD under all ionic strength conditions used in this assay; however, the antifungal activity of CatD became weaker with increasing ionic strength, whereas that of the wild type was maintained. The results at high ionic strength further verified the contribution of the CBM18 domain to the antifungal ability of GlxChiB. The microscopic observations clearly showed that the wild type acted on both the tips and the lateral wall of fungal hyphae, while CatD acted only on the tips. These results suggest that the CBM18 domain could contribute to the antifungal ability of chitinase through its affinity to the fungal lateral wall by hydrophobic interactions.