Team:Wageningen UR/project/fungal sensing
From 2014.igem.org
Fungal inhibition
Overview
In order to inhibit F.oxysproum growth, several anti-fungal substances will be produced when fusaric acid is sensed. Those being 2,4-DAPG, chitinase, DMDS,DMTS and pyoverdine. 2,4-DAPG or 2,4-Diacetylphloroglucinol is a widely used antiobiotic against plant pathogens. Chitinase is a lytic enzyme that breaks down fungal cell walls. Dimethyldisulfide (DMDS) and dimethyltrisulfide (DMTS) are sulfur by-products produced by P.putida and have shown to produce plant growth and inhibit F.oxyposrum respectively. And lastly, pyoverdines are iron chelating compounds that are produced when iron is limited in order to scavenge for iron to induce iron competition. With these anti-fungal substances our engineered P.putidawill be able to sense F.oxypsroum and in turn produce substances that will eliminate or inhibit F.oxysporum from in the soil.
2,4-Diacetylphloroglucinol(2,4-DAPG)
2,4-DAPG, full name 2,4-diacetylphloroglucinol is an antibiotic that is widely used in the agricultural industry against pathogens. It’s a broad spectrum antibiotic has been shown to play a key role in the biological control of various plant pathogens including F. oxysporum(Belgrove 2007). In addition to that, it has also shown to induce systematic resistance (ISR) in plants (Rezzonico, Zala et al. 2007). Since P. putida does not produce DAPG by itself, a gene cluster obtained from P.flourescens will be introduced into P. putida. The phl gene cluster contains eight genes, from phlA to phlH. Gene cluster phlABCDE will be used for this project as literature has shown that phlABCD are synthesis genes and phlE codes for an efflux pump (Bangera and Thomashow 1999) (Abbas, McGuire et al. 2004). phlABCD has been expressed before in P.putida and has shown to produce 2,4-DAPG (Bakker, Glandorf et al. 2002).
Dimethyldisulfide (DMDS) and dimethyltrisulfide (DMTS)
When breaking down methionine for ammonium, methanethiol gets formed as a side product. Then methanethiol gets oxidized into dimethyldisulphide (DMDS) and dimethyltrisulphide (DMTS) (see figure 2, pathway 1). DMTS was shown to have an inhibitory effect against foc with starting inhibition of 78% but then slowly declined to 26% (Zhang, Mallik et al. 2013). DMDS is used as plant growth promoter and at the same time also shown a slight inhibition to foc of 10% (Meldau, Meldau et al. 2013). Both DMTS and DMDS are naturally produced in P. putida but a higher production is desired. One thing that causes low yield of DMDS is the low affinity of methionine-γ-lyase to methionine meaning less formation of methanethiol, which then leads to low DMTS and DMDS production. So it was thought to overexpress an enzyme that has a higher affinity towards methionine and will therefor increase DMDS and DMTS production, this enyzme is a Methyl-γ-lyase from Brevibacterium linens that has shown to increase DMDS in Lactocossus lactis (Hanniffy, Philo et al. 2009). This gene was codon optimized and synthetically made for P.putida.
Results
2,4-DAPG
PhlABCDE was successfully cloned and put into SEVA 254 plasmid. Transformed in both E.coli and P.putida KT2440. Transformants were verified via colony PCR. For P.putida there was difficulty when doing colony PCR with Taq polymerase. It was never successful to get a full 5.4kbp band doing colony PCR with P.putida but when using a primer pair that forms a 1kbp product, it was then possible to see positive transformants.Verifying production of 2,4-DAPG via HPLC turned out to be difficult due to a lot of background noise of the samples, even after doing an extraction step. In order to test 2,4-DAPG against Fusarium, a in vitro assay was done on agar plates. Where different concentration of pure 2,4-DAPG were plated and <
Dimethyldisulfide (DMDS) and dimethyltrisulfide (DMTS)
Methionine-γ-lyase was successfully cloned and put into SEVA 254 plasmid. Transformed in both E.coli and P.putida KT2440. Transformants could be verified via colony PCR for E.coli but not for P.putida.
Pyoverdine
PfrI was successfully cloned and put into SEVA 254 plasmid. Transformed in both E.coli and P.putida KT2440 and checked via colony PCR. Growth experiments were done in minimal M9 medium supplemented with Iron was done with pyoverdine measured using spectrophotometer. Results can be seen in the (graph). As it seems that pfrI does not seem to affect the production of pyoverdine when in an iron rich environment.
Chitinase
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Future work
For future work, it would be nice it all the antifungal genes are coupled together behind the fusaric acid promoter in order to test production rate that is induced by fusaric acid. Also testing in the green house with a co-inoculation of F.oxysporum in order to see if production of the anti-fungals can reach high enough levels that it causes inhibition affect to F.oxysporum. This really depends on the amount of fusaric acid present in the soil when F.oxysporum is present.
References