Journal of Oceanology and Limnology   2021, Vol. 39 issue(3): 1010-1019     PDF       
http://dx.doi.org/10.1007/s00343-020-0203-6
Institute of Oceanology, Chinese Academy of Sciences
0

Article Information

YUE Yang, YU Huahua, LI Rongfeng, HU Linfeng, LIU Song, XING Rong'e, LI Pengcheng
Isolation and identification of antimicrobial metabolites from sea anemone-derived fungus Emericella sp. SMA01
Journal of Oceanology and Limnology, 39(3): 1010-1019
http://dx.doi.org/10.1007/s00343-020-0203-6

Article History

Received May. 19, 2020
accepted in principle Jul. 14, 2020
accepted for publication Aug. 5, 2020
Isolation and identification of antimicrobial metabolites from sea anemone-derived fungus Emericella sp. SMA01
Yang YUE1, Huahua YU1,2, Rongfeng LI1,2, Linfeng HU3, Song LIU1,2, Rong'e XING1,2, Pengcheng LI1,2     
1 Key Laboratory of Experimental Marine Biology, Center for Ocean Mega-Science, Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China;
2 Laboratory for Marine Drugs and Bioproducts, Pilot Qingdao National Laboratory for Marine Science and Technology, Qingdao 266237, China;
3 School of Chemistry and Chemical Engineering, Henan Institute of Science and Technology, Xinxiang 453003, China
Abstract: Marine symbiotic fungi represent an intriguing source of discovery of novel secondary metabolites with various biological activities. Sea anemones are benthic marine invertebrates, however, the cultivable symbiotic fungi residing in the sea anemones are paid few attentions compared to those derived from their cnidarian counterparts. Here we show the identification of antimicrobial secondary metabolites from the sea anemone-derived symbiotic fungi. Out of five isolated fungal strains, only the strain SMA01 showed strong antimicrobial activities, which was assigned into the genus Emericella based on the morphological characteristics and the ITS sequencing. Media swift from liquid fermentation to solid rice medium presented little influence on its antibacterial activity. A chemical investigation of the ethyl acetate extract of the Emericella sp. SMA01 led to discovery of the primary antibiotic metabolite phenazine-1-carboxylic acid. The IC50 values of the phenazine-1-carboxylic acid against Phytophthora capsici, Gibberella zeae, and Verticillium dahliae were determined to be 23.26-53.89 μg/mL. To the best of our knowledge, this was the first report of Emericella sp. in sea anemones. The current study may benefit understanding of the defensive chemical interactions between the symbiotic fungi and their host sea anemones.
Keywords: sea anemone    symbiotic fungi    phenazine-1-carboxylic acid    antimicrobial activity    
1 INTRODUCTION

Marine invertebrates are increasingly becoming an important source of marine symbiotic fungi. These symbiotic fungi constitute an interesting group of marine fungi since most of them are convinced to be a reservoir of diverse compounds with structural and functional novelty (Bugni and Ireland, 2004; Saleem et al., 2007; Jones et al., 2008). In the past few years, novel secondary metabolites from marine-sourced fungi increased rapidly, more than 600 new compounds reported in 2018 according to the Natural Product Reports (Carroll et al., 2020). The novel compounds from marine-derived fungi are found to possess a variety of biological activities, including antimicrobial, cytotoxic, and radical scavenging activities, but their ecological roles are barely understood. Many studies have proven that some metabolites initially isolated from marine invertebrates are actually produced by their symbiotic microbes (Piel, 2009; Schmidt et al., 2012). In the hostile ocean environments, marine invertebrates always harbor a number of microbial symbionts, which could produce various compounds protecting the host animals from microbial infections or predatory (Schmidt, 2008). Discovery of new antibiotics from the alternative chemical defense strategy represents an important trend in marine natural products.

Sea anemones belong to the phylum Cnidaria, class Anthozoa, subclass Hexacorallia. Sea anemones are benthic marine invertebrates, which possess a soft body and have a sessile lifestyle. Lacking physical protection, they may also utilize the chemical defense strategy to immune themselves from environmental noxious stimuli such as infectious microorganisms (Paul et al., 2007; Schmidt, 2009). Like most other cnidarians, sea anemones produce various biologically active substances ranging from small-molecule natural products to biomacromolecules, such as cytolysins and phospholipases (Rojko et al., 2016; Guillen et al., 2020). The small-molecule natural products from sea anemones cover a variety of structural types, including alkaloids, sterols, terpenes, and so on (Guillen et al., 2020). Living on the bottom of the ocean, sea anemones were also found to form complex interactions with various microorganisms, which were recently proven a great source for antibacterial compounds. In the microbiomes of two investigated sea anemones, Bacillus and Vibrio species were found to the dominate bacteria producing antimicrobial substances (León-Palmero et al., 2018). Besides bacteria, fungi derived from sea anemones were good candidates for producing novel antimicrobial secondary metabolites (Yang et al., 2012; Qin et al., 2015). However, compared to other marine invertebrates such as sponges (Bolaños et al., 2015; Calabon et al., 2019), corals (Amend et al., 2012; Zhang et al., 2012) and ascidians (LópezLegentil et al., 2015; Chen et al., 2018), sea anemonesassociated fungi are currently less investigated. In the present study, we attempted to isolate and identify the sea anemone-derived fungi and further identified the antimicrobial metabolites against a panel of human bacterial pathogens and plant pathogenic fungi.

2 MATERIAL AND METHOD 2.1 General experimental procedures

NMR spectra were recorded using a 600-(1H) and 150-(13C) MHz Bruker spectrometer with tetramethylsilane (TMS) as the internal standard. UV spectra were determined with a TU-1810 UV-Visible spectroscopy system. Electrospray ionization mass spectroscopy (ESI-MS) was performed on Finnigan Thermo spectrometer. Silica gel (200−300 mesh; Qingdao Haiyang Chemical Co. Ltd., China) and Sephadex LH-20 (GE, U.S.A) were used for column chromatography. TLC was carried out with pre-coated silica gel GF254 plates (Qingdao Haiyang Chemical Co. Ltd., China). Compounds were visualized under UV light or by spraying with H2SO4-EtOH (1꞉9, v/v) followed by heating.

2.2 Fungal material

Three sea anemone individuals were collected in September 2013 from the First Bathing Beach, Qingdao, China. Isolation of symbiotic fungi were performed as previously described (Yue et al., 2015). Briefly, after sterilization and washing with 75% ethanol and sterile natural seawater, the sea anemone individuals were cut into cubes of 0.5 cm3 and immediately placed in plates containing PDA medium (10-g sea salts, 20-g dextrose, 20-g agar powder and 1-L 20% (w/v) potato soup, natural pH). The plates were incubated at 28 ℃ for 1–3 weeks. Colonies growing around the tissue cubes were picked up for isolating pure strains. And the resultant pure strains were incubated on Wickerham' medium (3-g yeast extract, 3-g malt extract, 5-g peptone, 10-g glucose in 1-L 75% natural seawater, 18-g agar, pH 7.2–7.4) slants at 4 ℃ for short-term storage.

2.3 Phylogenetic analysis

DNA extraction procedure of the isolate SMA01 was same as the method reported previously (Yue et al., 2015). The resultant DNA sequences were submitted to NCBI database and compared with other sequences in the BLASTn algorithm. For phylogenetic analysis, 38 similar sequences corresponding to the ITS region were extracted from NCBI database and submitted to MUSCLE for sequence alignment with default parameters, together with SMA01 and Penicillium expansum (chosen as the outgroup taxon). In addition, the resultant dataset was further manually edited in MEGA 6.06 and analyzed in PHyML 3.1 using maximum likelihood with a bootstrap analysis of 1 000 replicates. The tree was viewed and edited in Figtree 1.1. Results strongly indicate the isolate SMA01 belonged to the genus Emericella. The ITSrDNA sequence of isolate Emericella sp. SMA01 was deposited in GenBank under the accession number of KM390915.

2.4 Small-scale fermentation and screening for antibacterial activity 2.4.1 Small-scale fermentation of five sea anemoneassociated fungi

For small-scale fermentation, fungi were cultured for seven days on PDA, and then mycelium-containing plugs (Φ=5 mm) were punched and carefully placed in 1-L flasks containing Liquid Wickerham's Broth (WMB: 3-g yeast extract, 3-g malt extract, 5-g peptone, 10-g glucose in 1-L 75% natural seawater, pH 7.2–7.4) for fermentation. After 4–6 weeks of cultivation at room temperatures, about 200 mL of ethyl acetate (EtOAc) were added into each flask. Then, the flasks were left closed for 2 days. The liquid cultures were separated from the mycelia by filtration and extracted with EtOAc (3×250 mL). The organic layers were collected and dried over anhydrous MgSO4, then concentrated in vacuo to afford 5 EtOAc extracts for screening of antibacterial activity.

2.4.2 Cultivation of isolate SMA01 in solid rice media

As an alternative way, the isolate SMA01 initially cultivated in liquid WMB media was cultured in solid rice media (RM, containing 100-g rice, 110-mL 100% seawater containing 0.3% peptone). After cultivation for 4–6 weeks at room temperatures, the cultures were crushed mechanically and then extracted with EtOAc (3×500 mL) in an Ultraturrax (JY92-II, Scientz) at 600 W for 2×90 cycles of running for 20 s with an internal of 5 s. The homogenates were subject to filtration with medical gauze and the organic layer was collected. After removing the solvent in vacuo, 3.6-g crude extract was obtained for preliminary isolation. Crude EtOAc Extract (3.6-g gum) was isolated by Vacuum Liquid Column chromatography (VLC, 30 g, 230–400 mesh Silica gel 60) with stepwise mobile phase CH2CH2꞉MeOH from 100꞉1 to 0꞉1 to afford six fractions, which were further combine into four fractions (Fr.) A–D. To track the antibacterial compounds, the fractions were submitted to screening of antibacterial activity against five bacterial pathogens.

2.5 Large-scale fermentation, extraction and bioassay-guided separation of phenazine-1- carboxylic acid

The isolate Emericella sp. SMA01 was cultivated in 30-L Wickerman's Medium containing 3-g yeast extract, 3-g malt extract, 5-g peptone, 10-g glucose in 1-L 75% natural seawater, pH 7.2–7.4 for 38 days without shaking. The mycelia and fermentation broths were separated by filtration with 200-mesh plankton net and the filtrate was extracted 3 times with 20-L EtOAc. The organic layers was combined and dehydrated with anhydrous MgSO4. Crude EtOAc extract was obtained as dark gum after concentrated under reduced pressure. The mycelia were excised and extracted three times with 3-L acetone. After removing the solvent, the aqueous layer was extracted twice with equal volume of EtOAc. Two EtOAc extracts from fermentation broth and mycelia were combined because of similar TLC and HPLC pattern observed. Finally, 7.8-g dark brown gum was obtained for further isolation of antimicrobial compounds.

7.8-g crude extracts were subjected to VLC chromatography (80 g, 230–400 mesh Silica gel 60) with stepwise mobile phase Petroleum Ether (PE)- EtOAc (0–100%) and CHCl3-CH3OH (5%–100%) to afford fractions Fr.1–14. According to the antibacterial assays using bacterial pathogen Staphylococcus aureus as indicator strain, we found seven fractions Fr.4–Fr.8, Fr.13, Fr.14 possessed significantly antibacterial activity against S. aureus, of which Fr.5 showed highest antibacterial activity with inhibitory zone of 21.3 mm (Supplementary Fig.S1). Then, Fr.5 (185 mg) was subject to VLC column chromatography (30 g, 230–400 mesh Silica gel 60) with increasing polarity of CH2Cl2꞉MeOH (50꞉1–0꞉1) to yield six subfractions. Subfractions Fr.5-3 were subject to repeated LH-20 separation with CH2Cl2꞉MeOH=1꞉1 and preparative-TLC (pTLC) with Hexane꞉CH2Cl2꞉ EtOAc (10꞉50꞉1, 0.1% HCOOH) to obtain Compound 2 (3.1 mg, yellow needles, Rf=0.45). Compound 3 (4.2 mg) was separated from Fr.3 (inhibitory zone, 8 mm) by recrystallization in dichloromethane. Detailed spectral data of compounds 2–3 were presented in the supporting information (Supplementary Figs.S2–S7).

2.6 Antimicrobial disk susceptibility tests

For screening antibacterial compounds from five sea anemone-derived fungi cultivated in WMB media, six bacterial pathogens, and three plant pathogenic fungi deposited in our laboratory was used. They are S. aureus, Bacillus subtilis, Escherichia coli, Salmonella enterica, Bacillus anthracis, Clostridium Perfringens, Glomerella cingulate, Gibberella zeae, and Fusarium oxysporum.

For screening antibacterial compounds from RM culture of isolate Emericella sp. SMA01, five bacterial pathogens purchased from CGMCC including two Gram-positive bacteria (S. aureus subsp. aureus CGMCC 1.879=CMCC 26001, B. subtilis subsp. subtilis CGMCC 1.3382=ATCC 11774), two Gram-negative bacteria (E. coli CGMCC 1.872=CMCC 44568, S. enterica subsp. enterica CGMCC 1.10754=ATCC 19585), and one marine fish pathogens (Vibrio Parahaemolytic CGMCC 1.1616=ATCC 33847) were used.

Antimicrobial activities of EtOAc extracts, fractions, and pure compounds were performed according to the Antimicrobial Susceptibility Testing Standards M2-A11 as described previously (Yue et al., 2015). Briefly, the microbial strains for test were recovered from 4 ℃ and inoculated on MuellerHinton Agar (MHA) plates overnight aerobically in a 37 ℃ incubator. Single colonies were picked up and suspended into Mueller-Hinton Broth, which was adjusted to match the 0.5 Mcfarland standards. Then, the suspensions were evenly spread on MHA plates using cotton swab. The EtOAc extracts from five sea anemone-associated fungi were resolved in 0.5–1.0-mL DMSO. VLC fractions were prepared for antibacterial assays by resolving 100–200-mg fractions in 1.0-mL DMSO. 10–15 μL of EtOAc extracts and 5 μL of fractions or pure compounds were pipetted onto sterile paper disks (5-mm diameter). After removing the DMSO at room temperature, the paper disks were placed on the surface of indicator medium plates in duplicates. After inoculation for 18 h at 37 ℃, the inhibitory activity was determined by measuring the diameter of inhibitory zone (diameter, mm). DMSO was used as negative control. Penicillin G potassium salt (MDBio, Inc, 20 μg/mL in DMSO) and streptomycin sulfate (Sigma, 20 μg/mL in DMSO) were used as positive control, respectively.

2.7 Antifungal assays

Three plant pathogenic fungi, Phytophthora capsici, Verticillium dahlia CGMCC 3.375 8, Gibberella zeae CGMCC 3.428 8, were used in this study. Antifungal bioactivity of the compound 2 was conducted according to the method described in literature (Zhang et al., 2013). Briefly, 10.6 mg of compound 2 were dissolved in 2 mL of DMSO, and diluted in 2-fold way, yielding seven concentration gradients. 100 μL of the 2-fold diluted solutions were added into 10 mL of liquid potato dextrose agar at final concentrations of 0.83–53 μg/mL. Agar plugs containing the fungal mycelia were inoculated onto the center of PDA plates, respectively. Then, the plates were placed in an incubator at 28 ℃. 1% (w/w) DMSO was used as a negative control, when the fungal mycelium reached the edges of the control dishes, the antifungal activities were calculated as follows, and the experiments were carried out in triplicates.

where De, the diameter of the growth zone in the experimental dish (mm); Dc, the diameter of the growth zone in the control dish (mm).

2.8 Statistical analysis

Results are expressed as mean±S.E.M. The significance of differences between the means of different experimental groups was analyzed by Analysis of Variance, followed by Tukey multiple comparisons test build in Graphpad Prism 6.0 (GraphPad software, San Diego, CA, USA). P < 0.05 was considered statistically significant.

3 RESULT 3.1 Isolation of sea anemone-associated fungi and screening of the antibacterial potential

The sea anemones were collected in the First Bathing Beach of Qingdao and were used to isolate the symbiotic fungi (Fig. 1a). In total of five pure fungal isolates were obtained from inner tissues of the sea anemones in PDA plates (Fig. 1b). To investigate their antibacterial potential, all 5 isolates were fermented in small scale with liquid Wickerman's media, and then EtOAc extracts from the liquid cultures were employed to assay the antibacterial activities against a panel of bacterial pathogens by disc diffusion assay. Results are shown in Fig. 2a. Of all the test samples, EtOAc extracts from the isolate SMA01 possessed the highest antibacterial activity against all tested pathogens, inhibitory zone ranging from 10 mm to 15 mm (Fig. 2a). Moreover, EtOAc extracts from another three isolates showed relatively mild antibacterial activities with average inhibitory zone of 5–10 mm.

Fig.1 Photos of the sea anemone investigated in this study (a); the strain SMA01 isolated from the inner tissues of the sea anemone host (b); and the microscopic image of characteristic spore produced by the strain SMA01 (40×) (c)
Fig.2 Screening of antimicrobial activities of EtOAc extracts from five sea anemone-derived fungi (a) and subfractions from strain SMA01 (b) a. number 1 represents the EtOAc extract from strain SMA01. Results were calculated from 2 replicates and expressed as the mean inhibitory zone (mm). Dashed circle indicates the antifungal activities against three pathogenic fungi; b. red circle indicates that the average inhibitory zone from 3 replicates is more than 15 mm; orange: 13.5 mm; yellow: 10-11 mm; blue: 9 mm; light blue: 7 mm; grey: 5 mm. Abbreviations: VP: Vibrio Parahaemolytic; SE: Salmonella enterica; SA: Staphylococcus aureus; BS: Bacillus subtilis; EC: Escherichia coli.

To validate the antibacterial potential of isolate SMA01, we also cultivated this fungal in solid rice media in small scale. The EtOAc extract was obtained after fermentation and used to trace its antibacterial activity. After preliminary isolation by normal phase vacuum liquid chromatography with CH2Cl2꞉MeOH (100꞉1–0꞉1), four subfractions Fr.A–D were obtained from the EtOAc extract and were further assayed for antibacterial activity. Results indicated that subfraction Fr.A, eluted with CH2Cl2꞉MeOH (100꞉1– 10꞉1), exhibited significantly antibacterial activity against Vibrio Parahaemolytic, Staphylococcus aureus and Bacillus subtilis (Fig. 2b). While other subfractions except for Fr.B, showed mild inhibitory effects against one or two bacterial pathogens. These results indicate that isolate SMA01 is a good candidate for isolation of active secondary metabolites.

3.2 Identification of the sea anemone-derived fungi SMA01

The potential antibiotics-producing isolate SMA01 was further identified by morphology and ITS-rDNA sequencing. One representative stain and its characteristic spore structure are shown in Fig. 1b–c. The colonies of isolate SMA01 on MEA are flat with white aerial mycelium on the edge, and are covered by yellow conidia in the center (Fig. 1b). The spore structure is shown in Fig. 1c, which indicate that the strain SMA01 may belong to the genus Aspergillus. However, the morphological characteristics is not enough to assign the identity of this strain exactly, thus molecular identification based on ITS-rDNA sequencing was performed. A sequence of 482 bp was obtained from the ITS-rDNA region and was submitted to BLASTn for searching similar species in the database. A phylogenetic tree was constructed based on 39 similar ITS-rDNA sequences downloaded from the BLAST results and the results strongly suggest that strain SMA01 belonged to genus Emericella (Fig. 3).

Fig.3 Neighbor-joining phylogenetic tree from analysis of 38 similar rDNA-ITS sequences of strain SMA01 Bootstrap values are indicated in different colors of each branch based on a neighbor-joining analysis of 1 000 replicates.
3.3 Separation and identification of antibacterial and antifungal compound phenazine-1-carboxylic acid from Emericella sp. SMA01 liquid cultures

The fungal strain Emericella sp. SMA01 was cultivated in liquid WMB media for 38 days at room temperature, and then EtOAc extracts from the liquid cultures was obtained and further isolated by a combination of silica gel column chromatography, Sephadex LH-20 and preparative TLC according to the antibacterial activity against an indicator strain S. aureus. Figure 4 shows the schematic flowchart of isolation of antibacterial Compound 2.

Fig.4 Schematic illustration of isolation of antimicrobial compound 2 from EtOAc extracts of liquid cultivation of Emericella sp. SMA01 Flags represent the maximum antibacterial activity against S. aureus.

Compound 2 (3.1 mg) was obtained as yellow needles. In the 1H NMR spectrum, signals for seven aromatic protons were observed at δH 7.21–8.98. Moreover, at downfield, chemical shift corresponding to δH 15.55, one singlet changeable proton, probably -OH, was observed. 13C NMR highlighted the feather that only twelve aromatic cartons (δC 125.06–144.21) existed together with a carbonyl carbon (δC 166.04). DEPT 135 revealed seven primary carbons of twelve aromatic cartons existed. According to the NMR data, a carbonyl group and at least one benzene ring were deduced. Further literature survey suggested that the NMR characteristics of compound 2 was in accordance with the known compound phenazine-1-carboxylic acid (Jayatilake et al., 1996). MS analysis of compound 2 affirmed our deduction that compound 2 was phenazine-1-carboxylic acid with m/z 223.05 (ESI-MS, [M-H]-).

Compound 3 (4.2 mg) was obtained as white needles. Interpretation of 1H and 13C NMR data suggested that compound 3 was in accordance with previously reported Ergosta-5, 7, 22-trien-3β-ol (Wang et al., 2004). Therefore, compound 3 was identified as Ergosta-5, 7, 22-trien-3β-ol.

Figure 5 shows the antifungal effects of phenazine- 1-carboxylic acid against three phytopathogenic fungi. Results suggested that phenazine-1-carboxylic acid exhibits significantly antifungal activity below 53 μg/ mL. The IC50 values against Phytophthora capsici, Gibberella zeae (CGMCC 3.428 8) and Verticillium dahliae (CGMCC 3.375 8) were determined to be 23.26, 30.67, and 53.89 μg/mL, respectively, by the Probit analysis built in SPSS software. Therefore, phenazine-1-carboxylic acid shows the most powerful inhibition against the P. capsici.

Fig.5 Antifungal activities of phenazine-1-carboxylic acid against three phylopathogenic fungi Results were calculated from three replicates and expressed as mean±S.E.M. The dotted lines represent the 50% inhibition and IC50 values are evaluated by Probit analysis build in SPSS software and shown in the rectangular boxes.
4 DISCUSSION

Sea anemones were renowned as venomous animals in nature for producing neurotoxic toxins, while their associated fungi were not investigated enough. In this study, 5 sea anemone-associated marine fungi were isolated and assayed for antibacterial activity against a panel of bacterial pathogens. One fungal strain whose metabolites possessed potent antibacterial activity and chemical diversity was found and was further identified as Emericella sp. according to the morphological characteristics and ITS-rDNA sequence. Moreover, bioassay-guided isolation of active metabolites against S. aureus led to a known antibiotics, phenazine-1-carboxylic acid, in subfraction Fr.5. Importantly, phenazine-1-carboxylic acid was found to inhibit three phytopathogenic fungi with IC50 values ranging 23.26 μg/mL to 53.89 μg/mL, which extended our knowledge of the applications of the compound phenazine-1-carboxylic acid.

In 2001, 23 fungal strains isolated sea anemones Anthopleura qingdaoenisis Pei and A. midori were grouped in to six genera, including Rhozopus, Penicillium, Alterinaria, Aspergillus, Dospora, Fusarium, and Gliocladium (Liu et al., 2001). Da Silva et al. (2008) reported 110 fungal species within eight genera from sea anemones Palythoa caribaeorum, P. variabilis, and Zoanthus solanderi. Moreover, the culturable fungal diversity of sea anemone P. haddoni in the South China Sea was demonstrated by identifying 49 independent fungal strains, of which 25 fungal isolates fell into 18 genera (Qin et al., 2015). Recently, sea anemone Anthopleura xanthogrammicawas found to harbor phylogenetically diverse fungi of 18 genera, of which Aspergillus dominated (Liu et al., 2020). Of special, the genus Emericella was not included in above sea anemonederived fungi. The genus Emericella had been reported previously as plant endophytic fungi (Xu et al., 2013) and in various marine environments such as green alga (Oh et al., 2007), sponge (Malmstrøm et al., 2002), jellyfish (Malmstrøm, 1999), and marine sediments (Fredimoses et al., 2019). To the best of our knowledge, it was the first report of Emericella sp. in sea anemones.

Numerous studies have indicated that organic extracts from marine invertebrates-associated microorganisms possessed antibacterial activity. In the case of corals, approximately 20%–70% microbes exhibited considerable antibacterial activity (ShnitOrland and Kushmaro, 2009; Nithyanand et al., 2011). Investigation on the antibacterial activities of organic extracts from the sea anemone-associated fungi revealed similar phenomenon with coralrelated microorganisms, up to 59% of the culturable fungi possessing antimicrobial activity (Qin et al., 2015; Liu et al., 2020). In this study, all isolated fungal strains exhibited different levels of antibacterial activity, however, only Emericella sp. SMA01 showed the strongest inhibitory effects against a panel of human bacterial pathogens (Fig. 2a). Moreover, the shift from liquid fermentation to solid rice medium presented little influence on the antibacterial activity of the Emericella sp. SMA01, which indicated that Emericella sp. SMA01 may be a good producer for synthesizing antibacterial secondary metabolites.

Recent years witnessed an increasing evidence of producing novel antimicrobial secondary metabolites by the Emericella spp. from different source organisms. These novel natural products covered a broad range of structural characteristics from cyclic peptides (Malmstrøm, 1999), polyketides (Pang et al., 2018), to meroterpenoids (Chen et al., 2019; Li et al., 2019). Moderate to potent antimicrobial activities were usually observed against either human bacterial pathogens or plant pathogenic fungi among these metabolites. Noteworthy, emervaridones A from Emericella sp. TJ29 showed significant inhibition to extended-spectrum β-lactamase-producing E. coli with an minimum inhibitory concentration value of 2 μg/mL, which was comparable to the clinically used antibiotic amikacin (He et al., 2017). In this study, bioassay-guided isolation led to a known antibiotics, phenazine-1-carboxylic acid, from the Emericella sp. SMA01. Phenazine-1-carboxylic acid was able to inhibit three phytopathogenic fungi with IC50 values ranging from 23.26–53.89 μg/mL. Phenazine-1- carboxylic acid is a natural phenazine antibiotics, mainly isolated from plant rhizosphere-symbiotic bacteria Pseudomonas spp. for biocontrol of soilborne microbial pathogens (Thomashow et al., 1990; Mavrodi et al., 2006). Therefore, considering the occurrence of the Emericella spp. in plants and animals from a terrestrial or marine origin, the antimicrobial metabolites from Emericella spp. may play a vital role in protecting the sea anemone hosts from the environmental threat of pathogenic microorganisms. The fungal strain Emericella sp. SMA01 included in this study may have a great potential in developing into a biocontrol agent for prevention of agricultural microbial diseases.

5 CONCLUSION

In conclusion, investigation on the marine-derived fungi led to first isolation and identification of the Emericella sp. SMA01 in sea anemone with broadspectrum antibacterial activity in two different media. Tracing the antibacterial activity of the organic extract allowed identification a known antibiotic phenazine- 1-carboxylic acid, which also showed considerable inhibition to three phytopathogenic fungi with IC50 values of 23.26–53.89 μg/mL. This study extends our knowledge of sea anemone-associated fungi, and may benefit understanding of the defensive chemical interactions between the symbiotic fungi and their host sea anemones.

6 DATA AVAILABILITY STATEMENT

The datasets analyzed during the current study are available from the corresponding author on reasonable request.

References
Amend A S, Barshis D J, Oliver T A. 2012. Coral-associated marine fungi form novel lineages and heterogeneous assemblages. The ISME Journal, 6(7): 1291-1301. DOI:10.1038/ismej.2011.193
Bolaños J, De León L F, Ochoa E, Darias J, Raja H A, Shearer C A, Miller A N, Vanderheyden P, Porras-Alfaro A, Caballero-George C. 2015. Phylogenetic diversity of sponge-associated fungi from the Caribbean and the Pacific of Panama and their in vitro effect on angiotensin and endothelin receptors. Marine Biotechnology, 17(5): 533-564. DOI:10.1007/s10126-015-9634-z
Bugni T S, Ireland C M. 2004. Marine-derived fungi: a chemically and biologically diverse group of microorganisms. Natural Product Reports, 21(1): 143-163. DOI:10.1039/b301926h
Calabon M S, Sadaba R B, Campos W L. 2019. Fungal diversity of mangrove-associated sponges from New Washington, Aklan, Philippines. Mycology, 10(1): 6-21. DOI:10.1080/21501203.2018.1518934
Carroll A R, Copp B R, Davis R A, Keyzers R A, Prinsep M R. 2020. Marine natural products. Natural Product Reports, 37(2): 175-223. DOI:10.1039/C9NP00069K
Chen H Y, Liu T K, Yang J, Yang X L. 2019. Emerones A-C: three novel merosesquiterpenoids with unprecedented skeletons from Emericella sp.XL029. Organic & Biomolecular Chemistry, 17(36): 8450-8455. DOI:10.1039/C9OB01788G
Chen L, Hu J S, Xu J L, Shao C L, Wang G Y. 2018. Biological and chemical diversity of ascidian-associated microorganisms. Marine Drugs, 16(10): 362. DOI:10.3390/md16100362
Da Silva M, Passarini M R Z, Bonugli R C, Sette L D. 2008. Cnidarian-derived filamentous fungi from Brazil: isolation, characterisation and RBBR decolourisation screening. Environmental Technology, 29(12): 1331-1339. DOI:10.1080/09593330802379466
Fredimoses M, Zhou X F, Ai W, Tian X P, Yang B, Lin X P, Liu J, Liu Y H. 2019. Emerixanthone E, a new xanthone derivative from deep sea fungus Emericella sp SCSIO 05240. Natural Product Research, 33(14): 2088-2094. DOI:10.1080/14786419.2018.1487966
Guillen P O, Jaramillo K B, Genta-Jouve G. 2020. Marine natural products from zoantharians: bioactivity, biosynthesis, systematics, and ecological roles. Natural Product Reports, 37(4): 515-540. DOI:10.1039/C9NP00043G
He Y, Hu Z X, Li Q, Huang J F, Li X N, Zhu H C, Liu J J, Wang J P, Wang J P, Xue Y B, Zhang Y H. 2017. Bioassay-guided isolation of antibacterial metabolites from Emericella sp.TJ29. Journal of Natural Products, 80(9): 2399-2405. DOI:10.1021/acs.jnatprod.7b00077
Jayatilake G S, Thornton M P, Leonard A C, Grimwade J E, Baker B J. 1996. Metabolites from an Antarctic sponge-associated bacterium, Pseudomonas aeruginosa. Journal of Natural Products, 59(3): 293-296. DOI:10.1021/np960095b
Jones E B G, Stanley S J, Pinruan U. 2008. Marine endophyte sources of new chemical natural products: a review. Botanica Marina, 51(3): 163-170. DOI:10.1515/BOT.2008.028
León-Palmero E, Joglar V, álvarez P A, Martín-Platero A, Llamas I, Reche I. 2018. Diversity and antimicrobial potential in sea anemone and holothurian microbiomes. PLoS One, 13(5): e0196178. DOI:10.1371/journal.pone.0196178
Li Q, Chen C M, Cheng L, Wei M S, Dai C, He Y, Gong J J, Zhu R Q, Li X N, Liu J J, Wang J P, Zhu H C, Zhang Y H. 2019. Emeridones A-F, a series of 3, 5-demethylorsellinic acid-based meroterpenoids with rearranged skeletons from an endophytic fungus Emericella spTJ29. The Journal of Organic Chemistry, 84(3): 1534-1541. DOI:10.1021/acs.joc.8b02830
Liu C L, Tian L, Li G Y. 2001. The fungi from anemones in the intertidal zone of Qingdao sea area and the antimicrobial substance they produced. Chinese Journal of Marine Drugs, 20(6): 1-3. (in Chinese with English abstract) DOI:10.3969/j.issn.1002-3461.2001.06.001
Liu S, Ahmed S, Zhang C G, Liu T X, Shao C L, Fang Y W. 2020. Diversity and antimicrobial activity of culturable fungi associated with sea anemone Anthopleura xanthogrammica. Electronic Journal of Biotechnology, 44: 41-46. DOI:10.1016/j.ejbt.2020.01.003
López-Legentil S, Erwin P M, Turon M, Yarden O. 2015. Diversity of fungi isolated from three temperate ascidians. Symbiosis, 66(2): 99-106. DOI:10.1007/s13199-015-0339-x
Malmstrøm J, Christophersen C, Barrero A F, Oltra J E, Justicia J, Rosales A. 2002. Bioactive metabolites from a marine-derived strain of the fungus Emericella variecolor. Journal of Natural Products, 65(3): 364-367. DOI:10.1021/np0103214
Malmstrøm J. 1999. Unguisins A and B: new cyclic peptides from the marine-derived fungus Emericella unguis. Journal of Natural Products, 62(5): 787-789. DOI:10.1021/np980539z
Mavrodi D V, Blankenfeldt W, Thomashow L S. 2006. Phenazine compounds in fluorescent Pseudomonas spp.Biosynthesis and regulation. Annual Review of Phytopathology, 44: 417-445. DOI:10.1146/annurev.phyto.44.013106.145710
Nithyanand P, Indhumathi T, Ravi A V, Pandian S K. 2011. Culture independent characterization of bacteria associated with the mucus of the coral Acropora digitifera from the Gulf of Mannar. World Journal of Microbiology and Biotechnology, 27(6): 1399-1406. DOI:10.1007/s11274-010-0591-4
Oh D C, Kauffman C A, Jensen P R, Fenical W. 2007. Induced production of Emericellamides A and B from the marine-derived fungus Emericella sp.in competing co-culture. Journal of Natural Products, 70(4): 515-520. DOI:10.1021/np060381f
Pang X J, Zhang S B, Chen H L, Zhao W T, Yang D E, Xian P J, Xu L L, Tao Y D, Fu H Y, Yang X L. 2018. Emericelactones A-D: four novel polyketides produced by Emericella sp.XL 029, a fungus associated the leaves of Panax notoginseng. Tetrahedron Letters, 59(52): 4566-4570. DOI:10.1016/j.tetlet.2018.11.032
Paul V J, Arthur K E, Ritson-Williams R, Ross C, Sharp K. 2007. Chemical defenses: from compounds to communities. The Biological Bulletin, 213(3): 226-251. DOI:10.2307/25066642
Piel J. 2009. Metabolites from symbiotic bacteria. Natural Product Reports, 26(3): 338-362. DOI:10.1039/B703499G
Qin X Y, Yang K L, Li J, Wang C Y, Shao C L. 2015. Phylogenetic diversity and antibacterial activity of culturable fungi derived from the zoanthid Palythoa haddoni in the South China Sea. Marine Biotechnology, 17(1): 99-109. DOI:10.1007/s10126-014-9598-4
Rojko N, Dalla Serra M, Maček P, Anderluh G. 2016. Pore formation by actinoporins, cytolysins from sea anemones. Biochimica et Biophysica Acta (BBA) -Biomembranes, 1858(3): 446-456. DOI:10.1016/j.bbamem.2015.09.007
Saleem M, Ali M S, Hussain S, Jabbar A, Ashraf M, Lee Y S. 2007. Marine natural products of fungal origin. Natural Product Reports, 24(5): 1142-1152. DOI:10.1039/b607254m
Schmidt E W, Donia M S, McIntosh J A, Fricke W F, Ravel J. 2012. Origin and variation of tunicate secondary metabolites. Journal of Natural Products, 75(2): 295-304. DOI:10.1021/np200665k
Schmidt E W. 2008. Trading molecules and tracking targets in symbiotic interactions. Nature Chemical Biology, 4(8): 466-473. DOI:10.1038/nchembio.101
Schmidt E. 2009. Bacterial chemical defenses of marine animal hosts. In: White Jr J F, Torres M S eds. Defensive Mutualism in Microbial Symbiosis. Boca Raton: CRC Press, 65-83, https: //doi.org/10.1201/9781420069327.ch5.
Shnit-Orland M, Kushmaro A. 2009. Coral mucus-associated bacteria: a possible first line of defense. FEMS Microbiology Ecology, 67(3): 371-380. DOI:10.1111/j.1574-6941.2008.00644.x
Thomashow L S, Weller D M, Bonsall R F, Pierson III L S. 1990. Production of the antibiotic phenazine-1-carboxylic Acid by fluorescent Pseudomonas species in the rhizosphere of wheat. Applied and Environmental Microbiology, 56(4): 908-912. DOI:10.1128/AEM.56.4.908-912.1990
Wang F, Tan J W, Liu J K. 2004. Vibratilicin: a novel compound from the basidiomycete Cortinarius vibratilis. Helvetica Chimica Acta, 87(7): 1912-1915. DOI:10.1002/hlca.200490170
Xu Y M, Espinosa-Artiles P, Liu M X, Arnold A E, Gunatilaka A A L. 2013. Secoemestrin D, a cytotoxic epitetrathiodioxopiperizine, and Emericellenes A-E, five sesterterpenoids from Emericella sp.AST0036, a fungal endophyte of Astragalus lentiginosus. Journal of Natural Products, 76(12): 2330-2336. DOI:10.1021/np400762k
Yang K L, Wei M Y, Shao C L, Fu X M, Guo Z Y, Zheng C J, She Z G, Lin Y C, Wang C Y. 2012. Antibacterial anthraquinone derivatives from a sea anemone-derived fungus Nigrospora sp. Journal of Natural Products, 75(5): 935-941. DOI:10.1021/np300103w
Yue Y, Yu H H, Li R F, Xing R G, Liu S, Li P C. 2015. Exploring the antibacterial and antifungal potential of jellyfish-associated marine fungi by cultivation-dependent approaches. PLoS One, 10(12): e0144394. DOI:10.1371/journal.pone.0144394
Zhang X Y, Bao J, Wang G H, He F, Xu X Y, Qi S H. 2012. Diversity and antimicrobial activity of culturable fungi isolated from six species of the South China Sea Gorgonians. Microbial Ecology, 64(3): 617-627. DOI:10.1007/s00248-012-0050-x
Zhang Y L, Li S, Jiang D H, Kong L C, Zhang P H, Xu J D. 2013. Antifungal activities of metabolites produced by a termite-associated Streptomyces canus BYB02. Journal of agricultural and Food Chemistry, 61(7): 1521-1524. DOI:10.1021/Jf305210u