Antifungal Activity of Phenyl Derivative of Pyranocoumarin from Psoralea corylifolia L. Seeds by Inhibition of Acetylation Activity of Trichothecene 3-O-Acetyltransferase (Tri101)

Antifungal activity of petroleum ether extract of Psoralea corylifolia L. seed, tested against Fusarium sp. namely, Fusarium oxysporum, Fusarium moniliforme, and Fusarium graminearum, was evaluated by agar well diffusion assay. The chromatographic fractionation of the extract yielded a new phenyl derivative of pyranocoumarin (PDP). The structure of the PDP was confirmed using spectroscopic characterization (GC-MS, IR, and NMR), and a molecular mass of m/z 414 [M-2H]+ with molecular formula C27H28O4 was obtained. The PDP had a potent antifungal activity with a minimum inhibitory concentration of 1 mg/mL against Fusarium sp. Molecular docking using Grid-Based Ligand Docking with Energetics (GLIDE, Schrodinger) was carried out with the Tri101, trichothecene 3-O-acetyltransferase, as target protein to propose a mechanism for the antifungal activity. The ligand PDP showed bifurcated hydrogen bond interaction with active site residues at TYR 413 and a single hydrogen bond interaction at ARG 402 with a docking score −7.19 and glide energy of −45.78 kcal/mol. This indicated a strong binding of the ligand with the trichothecene 3-O-acetyltransferase, preventing as a result the acetylation of the trichothecene mycotoxin and destruction of the “self-defense mechanism” of the Fusarium sp.


Introduction
All over the world, a significant portion of agriculture production is lost due to fungal diseases and different mycotoxins produced by the phytopathogens like Aspergillus sp., Fusarium sp., and Penicillium sp. To overcome these losses in agricultural field, the common procedure is to use synthetic pesticides and fungicides [1,2]. These synthetic pesticides and fungicides cause several side effects which include carcinogenicity, teratogenicity, and residual toxicity [3,4]. Plant metabolites and plant-based pesticides and fungicides appear to be one of the better alternatives as they are known to have minimal environmental impact and danger to consumers in contrast to the synthetic pesticides [5,6]. To promote the proper use of botanicals and to determine their potential as a source for new fungicides, it is essential to study plants of medicinal value. Natural products of higher plants may be a new source of antimicrobial agents with possibly novel mechanism of action contrary to synthetic drugs [7]. The seed of Psoralea corylifolia L. (Fabaceae), well known as traditional Chinese medicine "Buguzhi," is widely used for the treatment of various kinds of human disorders and contains good antioxidative, antimicrobial, antiinflammatory, antitumor, antimutagenic, and insect hormonal activities [8]. P. corylifolia L. seed has been reported to contain several phytoconstituents mainly coumarins, flavone components [9], and lactone as well as terpenoids like psoralen, isopsoralen, psoralidin, and bavachalcone [10].
With the aim of obtaining a bioactive principle, antifungal screening and activity-based fractionation of seed extract of P. corylifolia were carried out, which led to the isolation of the new phenyl derivative of pyranocoumarin (PDP). The compound had in vitro antifungal activity against the Fusarium sp. and molecular docking studies carried out  with the X-ray crystal structures of Tri101, trichothecene 3-O-acetyltransferase (PDB ID: 2RKV) available in the Protein Data Bank (PDB; http://www.pdb.org/pdb/) proposed a hypothetical mechanism for antifungal activity against Fusarium sp. The target protein selected for the molecular docking studies was a Tri101 gene product which catalyzes the transfer of an acetyl group from acetyl coenzyme A to the C3 hydroxyl moiety of several trichothecene mycotoxins. It has been reported that Tri101 acetylation was the primary defense mechanism against 3-hydroxylated trichothecenes in Fusarium sp. and that a mutation or a modification, resulting in a loss of Tri101, would be lethal to the organism [11].
When the pathway of the mycotoxin production in Fusarium sp. was analyzed, Tri101 gene product, that is, trichothecene 3-O-acetyltransferase catalyzes the acetylation of the C3 hydroxyl group of the toxin. The acetylation at C3 had been proposed to protect the Fusarium sp. through the remainder of the biosynthetic pathway. Tri101 will acetylate and reduce the toxicity of the final products of the biosynthetic pathway including trichothecene (T-2 toxin), nivalenol and deoxynivalenol [12][13][14]. The last step in the biosynthetic pathway is removal of the protecting C3 acetyl group before being secreted by the organism [15]. Control of the toxicity of trichothecene mycotoxins by modification of the C3 hydroxyl moiety has been identified as a self-defense mechanism of the organism.

Plant Material.
The plant specimen with the seed of Psoralea corylifolia was identified and certified by the Botanical Survey of India, Southern Circle, Coimbatore, Tamil Nadu, India. Voucher specimens were maintained in laboratory for future reference.

Microorganisms.
The fungal isolates of Fusarium sp. namely, Fusarium oxysporum, Fusarium graminearum, and Fusarium moniliforme from infected maize, paddy, and sorghum seeds were used for the study.

Extract Preparation.
The dried and powdered seed samples of P. corylifolia L. were extracted by overnight percolation with ethanol (polar solvent), chloroform (medium polar solvent) and petroleum ether (least polar solvent), at the rate of 1 : 5 at room temperature. The extracts were then filtered with country filter paper and concentrated under vacuum in a rotary evaporator to obtain a gummy residue [16].

Antifungal Studies by Agar Well Diffusion Assay.
The antifungal activity was tested for the prepared extracts against the selected pathogens. The sterilized sabouraud dextrose agar medium was poured into the petri plates and allowed to solidify. The fungal culture 200 μL was transferred to the petri plates. Using a sterile cork borer, wells of 6 mm in diameter were made in the plate containing the media. For each organism, 20 μL of the prepared sample was loaded in each well using sterilized dropping pipette. Three replications were maintained for each treatment. For each microorganism, the positive control (ketoconazole) and the negative control (ethanol) were also loaded in a separate well. The plates were incubated for 2-3 days and the observations were taken. The diameter of inhibition zone (DIZ) was measured and the mean D1Z was calculated [17,18].

Fractionation and Antifungal Assay.
The fractionation was carried out by column chromatography using a 22 cm long column having 1.6 cm diameter packed with 20 g of silica gel (60-120 mesh) using petroleum ether solvent. The active extract was loaded to the packed column and eluted with a 90 : 10 mixture of petroleum ether and ethyl acetate at a rate of 2.6 mL min −1 . The polarity of mobile phase was gradually increased using ethyl acetate to give different fractions. Fractions with similar thin layer chromatogram were pooled together which were labeled serially and then subjected to antifungal assay [17,18] to obtain the active fraction.

Minimum Inhibitory Concentration (MIC) by Tube
Dilution Method. The assay was performed to obtain the MIC of the active fraction isolated from petroleum ether extract of P. corylifolia L. seed against the selected fungal pathogens using tube dilution method. The MIC is defined as the lowest concentration of antibiotics or plant extracts that did not show any growth of tested pathogens. The entire test sample was dissolved in ethanol and diluted to the highest concentration (10 mg min −1 ) to be tested and then serial dilutions were made in a concentration range from 1 mg min −1 to 0.01 mg min −1 in sterile test tubes containing standardized inoculums. The growth of the organism for each dilution was observed and thus the MIC was evaluated.
Ketoconazole and ethanol were used as positive and negative control, respectively [16].   Square Deviation (RMSD) cutoff of 0.18Å and the resulting structure was used for docking [20]. The native ligand used was ZBA, a T2 mycotoxin which readily binds with protein trichothecene 3-O-acetyltransferase during the mycotoxin production and activates the selfdefense mechanism of the Fusarium sp.

Induced Fit Docking (IFD)
. IFD of the prepared ligand with the prepared protein was performed using IFD protocol of GLIDE v5.5 from Schrodinger Suite 2009 [20]. Both the ligand and the receptor were flexible which enabled the ligand to dock at the receptor's binding site and generate multiple poses of the receptor-ligand complex. Each docking included unique structural conformations of the receptor needed to fit the ligand pose. The IFD gives the best structure of the docked complex based on the Glide score (G-score) of the dockings.

Results and Discussion
The seed of P. corylifolia L. possesses several secondary metabolites with remarkable biological properties [9]. With this background the present research has been initiated to identify the active secondary metabolite compound produced by P. corylifolia L. seed against Fusarium sp.

Antifungal Activity and Fractionation
. Among the three extracts tested, petroleum ether extract exhibited highest zone of inhibition when compared to chloroform and ethanol extract at a concentration of 100 mg/mL against the selected pathogens. The DIZ produced by the petroleum ether extract (Table 1) was comparable to that of the positive control ketoconazole. The petroleum ether extract was fractionated and repeated fractionations yielded five different secondary fractions. The secondary fraction four (SF4) showed potent antifungal activity when compared to other fractions (Table 2). There is growing evidence that most of the secondary metabolites from plants are involved in the defense of the plant from plant pests and diseases. Thus, secondary compounds represent a large reservoir of chemical structures with biological activity. This resource is largely untapped for use as pesticides and fungicides [1].

Minimum Inhibitory Concentration.
The bioactive fraction SF4 showed inhibition at a concentration of 10 mg/mL and 1 mg/mL against the selected pathogens, while growth was observed in the other two dilutions 0.1 mg/mL and 0.01 mg/mL (Table 3). For the management and protection from plant diseases, exploitation of naturally available chemicals from plants would be a ecologically sound method and a prominent commercial fungicide can be obtained in future, replacing toxic fungicides [21,22].

Spectroscopic Studies.
The antifungal compound isolated from the seed of P. corylifolia L. was obtained as whitish slight yellow colored compound. The spectroscopic studies confirmed the presence of new phenyl derivative of pyranocoumarin. The molecular formula was determined   (Figures 4 and 5). This docking study proposes that the PDP has a similar affinity towards the trichothecene 3-O-acetyltransferase as that of the ZBA (T2 mycotoxin). Hence PDP can easily dock in the active site residue of the protein and form a docked complex and as a result prevent the activation of Tri101. This leads to the inhibition of acetylation of the T2 mycotoxin and disturbs the self-defense mechanism of the Fusarium sp.
Coumarins possess several biological activities, but they also play an important role in defense mechanisms against insects and plant pathogens. An increasing body of evidence indicates that the chemical interactions between plantpathogenic fungi and higher plants are both complex and highly integrated. For instance, as fungi have developed toxins that increase their virulence on plant tissues, plants have developed a variety of ways to limit the effectiveness of these fungal toxins. Biosynthesis of fungal toxins can, however be blocked in vitro by the addition of certain naturally occurring plant metabolites at concentrations inhibitory to fungal growth [27,28].

Conclusions
The seed of P. corylifolia L. is a commonly used botanical medicine. The present study has explored the use of P. corylifolia in the field of agriculture, by using it against plant pathogen Fusarium sp. A new antifungal compound, PDP, was identified with a minimum inhibitory concentration of 1 mg/mL against the selected pathogens namely, Fusarium oxysporum, Fusarium moniliforme, and Fusarium graminearum.
The molecular docking study with trichothecene 3-Oacetyltransferase proposes a hypothesis that the PDP has the affinity towards the target protein and it is able to bind with the protein and inhibit the acetylation mechanism of the protein leading to death of the Fusarium sp. The mechanism of how the antifungal compound PDP interacts with the 2RKV protein is revealed here. Nonetheless, this data require confirmation by appropriate experimental data. Our theoretical prediction may lead to the establishment of future molecular biology approaches.
Exploitation of naturally available chemicals from plants, which retards the reproduction of undesirable microorganisms, would be a more realistic and ecologically sound method for plant protection and will have a prominent role in the development of future commercial pesticides and fungicides for crop protection strategies, with special reference to the management of plant diseases [22,29]. The PDP can be used for developing a commercial formulation based on its field trial and toxicological experiments in future.