Friday, 07 September 2018 17:18

A Bacterial Compound May Fight an Important Crop Fungus

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Published in mBiosphere

rice field

Rice is one of the most important staple crops worldwide and provides 27% of the world’s dietary energy supply. To increase farming yields without increasing the need for fresh water, Chinese scientists have adapted several types of rice that can be grown in seawater. Unfortunately, salt water does not dissuade plant pathogens like the fungus Magnaporthe grisea from damaging crops, but a newly identified compound from a marine Bacillus subtilis isolate may be able to control fungal infection in the seawater-grown plants. The antifungal activity of the compound is characterized in a new Applied and Environmental Microbiology report.

 

AppEnvMicro: Fengycins, Cyclic Lipopeptides from Marine Bacillus subtilis Strains, Kill the Plant-Pathogenic Fungus Magnaporthe griseaby Inducing Reactive Oxygen Species Production and Chromatin Condensation

 

Rice blast disease caused by M. grisea infection can result in major crop damage, causing economic loss and affecting production of a food staple needed to feed half the world’s population. To search for a biological way to control infection, first author Linlin Zhang and senior author Chaomin Sun screened more than 400 marine bacteria for inhibition of M. grisea growth, identifying B. subtilis strain BS155 as the most inhibitory for fungal growth.

 

Bacillus subtilis fengycin inhibits Magnaporthe grisea growth(A) HPLC chromatogram of the active compound(s) from B. subtilis BS155. (B) Growth inhibition of M. grisea hyphal colonies by the active compound(s) from B. subtilis BS155. Source.

The source of inhibition was tracked to a secreted molecule in the fengycin family. Fengycins are cyclic lipopeptides with broad inhibitory activity against a number of filamentous fungi, and purified fengycins from BS155, identified by mass spectrometry, were confirmed to cause M. grisea inhibition (see figure, right). 

 

How do these fengycins, called collectively the BS155 fengycin by the researchers, inhibit fungal growth? Microscopic examination revealed fungal structural abnormalities in the presence of BS155 fengycin, which led the researchers to hypothesize that the compound damaged the cytoplasm, the cell and plasma membranes, leading to loss of cell integrity. Using microscopy and expression studies, the research team showed that treatment of M. grisea with fengycin B155 induces the release of reactive oxygen species, the condensation of chromatin, and inhibition of mitochondrial function, eventually leading to fungal cell death.

 

Using B. subtilis strains that produce fengycins and other antifungal compounds as a means of biocontrol has been suggested for protecting other crop species from fungal phytopathogens. Strains that naturally produce high concentrations of antifungal compounds may be especially important in organic farming, which cannot use industrial antifungal compounds on crops. Using a microbe to combat fungal infection may help farmers and gardeners alike by promoting healthy bacterial-plant interactions while maintaining a small ecological footprint on the surrounding microbial communities.

Last modified on Friday, 07 September 2018 17:33
Julie Wolf

Julie Wolf is the ASM Science Communications Specialist. She contributes to the ASM social media and blog network and hosts the Meet the Microbiologist podcast. She also runs workshops at ASM conferences to help scientists improve their own communication skills. Follow Julie on Twitter for more ASM and microbiology highlights at @JulieMarieWolf.

Julie earned her Ph.D. from the University of Minnesota, focusing on medical mycology and infectious disease. Outside of her work at ASM, she maintains a strong commitment to scientific education and teaches molecular biology at the community biolab, Genspace. She lives in beautiful New York City.

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