ConclusionsMicrobial metabolites wi

Conclusions
Microbial metabolites with antifungal activity have an
impact on crop protection as microbial fungicides
with new modes of action or as lead compounds for
novel synthetic fungicides. Blasticidin S, kasugamycin,
polyoxins and validamycins are being used in agriculture
worldwide as control agents of economically
important plant diseases. Soraphen A and strobilurins
exhibit novel modes of actions that are effective in
controlling fungal diseases of plants. In particular,
fenpiclonil, fludioxonil and synthetic derivatives of
strobilurins also have proved the excellent characteristics
of microbial metabolites as lead compounds for
fungicide development. The recent advance in microbial
fungicide development leads to discovery of new
microbial products with novel characteristics in the
future. However, as seen in many scientific
approaches, microbial fungicides have limitations in
their development and practical uses. One disadvantage
is the low productivity of fungicidal metabolites
by microorganisms when compared to the yields of
synthetic chemicals. The low yield rate increases the
cost for mass production of microbial metabolites,
leading to economically infeasible commercialization.
The second disadvantage is that microbial fungicides
may readily create pathogen strains resistant to the
fungicide, because of their highly specific mode of
action. The third obstacle is the increasing rate of
re-discovery of already known existing compounds.
Using novel screening methods for new targets provides
greater possibility of discovering novel antifungal
agents from microbial metabolites. However,
limitations to the development of microbial fungicides
may be overcome by rapid advances in the area of
crop protection. More efficient production of microbial
metabolites is possible by modern metabolic engineering
techniques. Studies of fungal physiology and
pathogenesis continue to generate novel targets specific
to plant pathogenic fungi. Biorational approaches
in designing new fungicides from lead compounds will
also be made possible by the extensive use of in silico
analysis.
Acknowledgements
This research was supported by grants from the BioGreen 21 program,
Ministry of Agriculture, Forestry and Fishery, Korea and a
grant (CG 1133) from the Crop Functional Genomics Center of the
21st Century Frontier Research Program funded by the Ministry of
Science and Technology, Korea, and a grant from the Center for
Plant Molecular Genetics and Breeding Research, Seoul National
University in Korea.