Team:Cornell/project/wetlab/fungal toolkit/antifungals

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During the growth phase of Ecovative’s fungal biomaterial production, molds and other fungi can contaminate and outcompete the growing mycelium.  These fungi compete in the well documented biological phenomenon called standoff where opposing fungal species will secrete enzymes designed to halt to growth of the competitor.  During our collaborations with Ecovative we identified various <i>Aspergillus</i> species (especially <i>Aspergillus fumigatus, Aspergillus niger</i>, and <i>Aspergillus brasiliensis</i>) as likely and potentially harmful contaminants.  To help reduce the harmful effects of these contaminants on the growing mycelium, we decided to pursue expressing antifungals in the growing mycelium to combat the Aspergillus species.  
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During the growth phase of Ecovative’s fungal biomaterial production, molds and other fungi can contaminate and outcompete the growing mycelium.  These fungi compete in the well documented biological phenomenon called standoff where opposing fungal species secrete enzymes designed to halt to growth of the competitor.  During our collaborations with Ecovative we identified various <i>Aspergillus</i> species (especially <i>Aspergillus fumigatus, Aspergillus niger</i>, and <i>Aspergillus brasiliensis</i>) as likely and potentially harmful contaminants.  To help reduce the harmful effects of these contaminants on the growing mycelium, we decided to pursue expressing antifungals in the growing mycelium to combat the Aspergillus species.  
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Expressing an antifungal within a fungus seems rather risky, as it could very well harm the wanted mycelium as much or more than the contaminants.  In our research, however, we managed to find an antifungal protein from the bacteria Streptomyces tendae that has specific activity toward <i>Aspergillus</i> species and is benign to many other fungi tested [1].  This antifungal protein will contribute to the standoff phenomenon and should give our mycelium a competitive advantage over its contaminants.   
Expressing an antifungal within a fungus seems rather risky, as it could very well harm the wanted mycelium as much or more than the contaminants.  In our research, however, we managed to find an antifungal protein from the bacteria Streptomyces tendae that has specific activity toward <i>Aspergillus</i> species and is benign to many other fungi tested [1].  This antifungal protein will contribute to the standoff phenomenon and should give our mycelium a competitive advantage over its contaminants.   

Revision as of 20:12, 27 September 2013

Cornell University Genetically Engineered Machines

Antifungals


During the growth phase of Ecovative’s fungal biomaterial production, molds and other fungi can contaminate and outcompete the growing mycelium. These fungi compete in the well documented biological phenomenon called standoff where opposing fungal species secrete enzymes designed to halt to growth of the competitor. During our collaborations with Ecovative we identified various Aspergillus species (especially Aspergillus fumigatus, Aspergillus niger, and Aspergillus brasiliensis) as likely and potentially harmful contaminants. To help reduce the harmful effects of these contaminants on the growing mycelium, we decided to pursue expressing antifungals in the growing mycelium to combat the Aspergillus species.

Expressing an antifungal within a fungus seems rather risky, as it could very well harm the wanted mycelium as much or more than the contaminants. In our research, however, we managed to find an antifungal protein from the bacteria Streptomyces tendae that has specific activity toward Aspergillus species and is benign to many other fungi tested [1]. This antifungal protein will contribute to the standoff phenomenon and should give our mycelium a competitive advantage over its contaminants.
Aspergillus niger
To test the activity of afp1 on Aspergillus niger, we ran a growth assay. E.coli BL21-AI cultures with sequence confirmed PT7 and afp1 plasmids were used as an antibiotic spread on CYM agar plates. Equal masses of Aspergillus niger were plated on these as well as empty and E.coli BL21 control plates. The mass of the plate was measured and compared to the original mass of the CYM agar plate. The governing principle behind this test is that as the fungi grow, the rate of respiration will increase, converting solid carbon compounds from the agar plate into CO2 gas and decreasing overall mass. If our construct was effective in inhibiting the growth of Aspergillus niger, then the afp1 plates should not decrease in mass as much as the controls. Our test revealed that mass loss was similar for all tests. We hypothesize that afp1 was not present at a high enough concentration to substantially inhibit growth. To further test this construct we plan on purifying the afp1 peptide to test effectiveness at higher concentrations and to experiment with a more susceptible species like Aspergillus fumigatus.

References

1. Bormann, C., Baier, D., Horr, I., Raps, C., Berger, J., Jung, G., & Schwarz, H. (1999). Journal of bacteriology.Characterization of a Novel, Antifungal, Chitin-Binding Protein from Streptomyces tendae Tü901 That Interferes with Growth Polarity,181(24), 7421-7429. Retrieved from http://www.ncbi.nlm.nih.gov/pmc/articles/PMC94197/