Chemical Composition, Algicidal, Antimicrobial, and Antioxidant Activities of the Essential Oils of Taiwania flousiana Gaussen

Taiwania flousiana (T. flousiana) Gaussen is a precious wood in the family Taxodiaceae. This study investigated the chemical components of the essential oil from the stem bark of T. flousiana and its algicidal, antifungal, and antioxidant properties. Sixty-nine compounds representing 89.70% of the stem bark essential oil were identified by GC-MS. The essential oil showed strong anti-algae, anti-bacteria, and anti-fungus activities against the tested species, and antioxidant activities. The IC50 values of the essential oil against chlorophyll a, chlorophyll b, and the total chlorophyll of Spirogyra communis (a species of algae), 24–96 h after the treatment, ranged from 31.77 to 84.92 μg/mL, while the IC50 values of butachlor ranged from 40.24 to 58.09 μg/mL. Ultrastructure changes revealed by the transmission electron microscopy indicated that the main algicidal action sites were the chloroplast and cell wall. The essential oil showed antifungal activities on Rhizoctonia solani (EC50 = 287.94 μg/mL) and Colletotrichum gloeosporioiles (EC50 = 378.90 μg/mL). It also showed bactericidal activities on Ralstonia solanacearum and Staphylococcus aureus, with zones of inhibition (ZOIs) being 18.66 and 16.75 mm, respectively at 40 μg/disk. Additionally, the essential oil possessed antioxidant activity estimated by 2,2-diphenyl-1-picrylhydrazyl (DPPH) method (IC50 = 33.51 μg/mL; IC50 value of the positive control ascorbic acid was 7.98 μg/mL). Thus, the essential oil of this plant might be used as a possible source of natural bioactive molecules in agrochemical industry as well as in food and cosmetic industries.


Introduction
T. flousiana (a synonym of Taiwania cryptomerioides Hayata), belonging to the family Taxodiaceae, is endemic to China. T. flousiana has been considered as one of the most precious woods in China for its outstanding quality. It has been used in construction industry, furniture industry, and paper industry [1][2][3]. Thus, the cultivation and plantation of T. flousiana have received significant attention [4][5][6][7][8]. The chemical constituents of the extract from the bark of T. flousiana have been investigated [9] and there were patents on the use of the chemicals from T. flousiana in medicinal industry [10]. Recently, a new chemical isolated from T. flousiana with strong herbicidal activity has been patented also [11]. However, it has not been previously investigated chemically for its essential oil.
In the production process of farm produce, various undesirable biotic factors such as algae and microbes can cause great loss of quantity and quality. Spirogyra (Zygnemataceae, Zygnematales) is a genus in the Class Zygnematophyceae (Conjugatophyceae), which is a member of the Infrakingdom Streptophyta. Spirogyra communis (Hassall) Kuetzing in the genus is widely distributed in freshwater habitats including flowing water, permanent ponds, and temporary pools and can cause great loss to farm produce [12,13]. Microbes such as Rhizoctonia solani, Fusarium moniliforme Sheld, and Fusariun oxysporun, etc., are common pathogens with a great diversity of host plants and can significantly reduce the quantity and quality of farm produce [14][15][16]. Normally, synthetic chemicals are extensively used to control them. However, the resistance issues caused by synthetic control agents are very common. Meanwhile, synthetic control agents lack selectivity and are toxic to non-target organisms.
As an important part of pesticides, the algicide resistance has been reported. Meanwhile, synthetic algicides such as diuron are toxic and have negative impact on the environment. Similarly, synthetic antimicrobial chemicals have the same problems [17,18]. Therefore, as an alternative to these synthetic control agents, natural compounds and extracts from plants are the main sources [19]. Among them, essential oil has received significant attention [20,21].
Consumers need natural control agents not only in the production process of farm produce, but also in food preservation process. Nowadays, antioxidants have been widely used as food additives to provide protection against oxidative degradation of foods by free radicals. Normally, synthetic antioxidants such as butylated hydroxyanisole have been widely used. However, the toxicity of synthetic antioxidants has been questioned. Thus, the development of natural antioxidants is warmly desired [22]. Plant-derived essential oil has also received significant attention in this field [23]. In this work, we extracted the essential oil of T. flousiana and further (i) identified its chemical constituents; (ii) investigated its algicidal, antifungal, antibacterial, and antioxidant activities; (iii) characterized its mechanisms as an algicide.

Algicidal Activity and Algicidal Mechanism of Action of T. flousiana Essential Oil
Algicidal activity of the essential oil extracted from stem bark of T. flousiana on S. communis was tested for the first time. The algicidal effects of T. flousiana essential oil on S. communis were dose-dependent at the concentrations from 12.5 to 200 µg/mL 24 to 72 h after the treatment.
The IC 50 values of the essential oil on the inhibition of chlorophyll a ranged from 40.64 to 90.10 µg/mL 24-96 h after the treatment. As a contrast, those of butachlor ranged from 36.60 to 55.28 µg/mL. The IC 50 values of the essential oil on the inhibition of chlorophyll b ranged from 53.39 to 106.91 µg/mL 24-96 h after the treatment. As a contrast, those of butachlor ranged from 47.29 to 79.12 µg/mL. Specially, 48 h after the treatment, The IC 50 values of the essential oil was 47.49 µg/mL, while that of butachlor was 62.95 µg/mL, indicating that the essential oil showed a better algicidal effect at 48 h after the treatment based on the inhibition of chlorophyll b. The IC 50 values of the essential oil on the inhibition of the total chlorophyll ranged from 31.77 to 84.92 µg/mL 24-96 h after the treatment. As a contrast, those of butachlor ranged from 40.24 to 58.09 µg/mL. Specially, 72 h after the treatment, the IC 50 values of the essential oils was 31.77 µg/mL, while that of butachlor was 40.91 µg/mL, suggesting that the essential oil showed a better algicidal effect at 48 h after the treatment based on the inhibition of chlorophyll b.
In summary, the algicidal activity of the essential oil was comparable to or even better than that of butachlor ( Table 2).

The Effect of Light on the Algicidal Activity of T. flousiana Essential Oil in S. communis
Further study revealed that light could affect the algicidal activity of T. flousiana essential oil in S. communis. 96 h after the essential oil treatment with light, the IC 50 values of the essential oil ranged from 71.58 to 87.89 µg/mL, which were much lower than the values without light ranging from 1156.28 to 1229.24 µg/mL (Table 3). This result indicated that some active ingredients of the essential oil were photo-activated.

Antibacterial Activities of T. flousiana Essential Oil
The in vitro antibacterial activities of T. flousiana essential oil, against four species of microorganisms were estimated by measuring the diameter of inhibition zone and varied by the sample types and bacteria strains. The T. flousiana essential oil showed obvious activity against Ralstonia solanacearum

Antioxidant Activity
Essential oils have been proposed as potential substitutes for synthetic antioxidants in food preservation because of their antioxidant activity [44]. In this work, the antioxidant activity of T. flousiana oil was determined by DPPH (2,2-diphenyl-1-picrylhydrazyl) scavenging assay. In this assay, the antioxidant reacts with the stable free radical 2,2-diphenyl-1-picrylhydrazyl with a deep violet color and produces 2,2-diphenyl-1-picrylhydrazine with no color [45]. The free radical scavenging activity is usually expressed either as percentage of DPPH inhibition or by the antioxidant consumption for a 50% DPPH reduction (IC 50 ). The amount of essential oil needed to decrease the initial DPPH by 50% (IC 50 ) is a parameter widely used to measure the antioxidant activity. The lower the IC 50 value, the more potent the antioxidant is. In our results, positive control ascorbic acid had the strongest antioxidant activity with IC 50 value of 7.98 µg/mL. The IC 50 value of the essential oil of T. flousiana was 33.51 µg/mL (Table 5), indicating it scavenged the free radical DPPH. All treatments were performed in triplicates and repeated at least three times. IC 50 : concentration (µg/mL) for a 50% inhibition.

Effects of Essential Oil on Algal Internal Structure
We found that the chloroplast disintegration and the shrink of plane transverse cell walls became more apparent with the increase of the essential oil concentration. With the treatment of 50 µg/mL, the chloroplast started to disintegrate. Meanwhile the structure of the chloroplast shrank. Severe damage of cell structure was observed at higher essential oil concentrations (100-200 µg/mL). In these treatments, plasmolysis occurred and damage to basic cell structure was severe, as revealed by the fact that the chloroplast disintegration became more apparent, and as well by damage to the plasma membrane and was accompanied by increased cell wall opacity. As a contrast, intact cell wall and normally distributed chloroplast were present in the control cells (Figure 3). The treated S. communis cells were analyzed by transmission electron microscope (TEM). Specifically, it was found that essential oil at 200 µg/mL could damage the cell wall and the chloroplast, leaving the cells vacuolated, with only some organelle remained in the cell ( Figure 4G-I). This result indicated that the main action site of the essential oil of T. flousiana might be the cell wall and chloroplast. It was noteworthy that the chloroplast is an important target of the essential oil of T. flousiana, this finding further supported our result that the light contributed to the algicidal activity of the oils presented in Table 3.
Further, we found that T. flousiana essential oil possessed inhibition of chlorophyll content on the S. communis, which is a species of algae. Harmful algae blooms have increased globally and many researchers are focusing on the development of the effective control agents. Plant-derived chemicals are important sources of selective and biodegradable algicides [49]. Recently, algicidal polyphenolic p-hydroxybenzoic acid, coumarin, and fatty acids have been isolated from different plants [50][51][52]. Wang et al. [53] reported the algicidal activities of essential oils from six plant species, namely, Potamogeton cristatus, Potamogeton maackianus, Potamogeton lucens, Vallisneria spinulosa, Ceratophyllum demersum, and Hydrilla verticillata. The inhibition rates of essential oils on M. aeruginosa were 30.2-41.7% at a concentration of 50.0 µg/mL. Phenolic and fatty acids were found to be the algicidal chemicals [54]. Normally, phenolic and fatty acids were the common components of essential oils, which provide useful information for further study of these chemicals in control of the submerged weeds. Notably, we found that light contributed to the algicidal activity of T. flousiana essential oil in S. communis. This indicated that some active ingredients of the essential oil were photo-activated, which deserves further study.
In 2017, Chen et al. reported that phytochemicals (ferruginol, T-cadinol, alpha-cadinol, and T-muurolol) of T. cryptomerioides heartwood had the potential to be used as environmentally benign antifungal agents against brown root rot fungus Phellinus noxius in place of synthetic or inorganic fungicides. Their results showed that ferruginol, T-cadinol, alpha-cadinol, and T-muurolol were found to exhibit excellent antifungal activities against P. noxius, with IC 50 values 16.9, 25.8, 33.8 and 50.6 µg/mL, respectively [55]. In our study, the content of ferruginol in T. flousiana essential oil was 3.94% and the oil also showed antifungal activity. Thus, the antifungal activity of the active ingredient ferruginol deserves more attention.
In 2002, Wang et al. demonstrated that ferruginol exhibited the strongest antioxidant activity among the diterpenes isolated from T. cryptomerioides heartwood [56]. In 2012, Ho et al. also reported that T. cryptomerioides twig essential oil showed antioxidant activity against DPPH. The IC 50 of the DPPH free radical scavenging capability of the essential oil was 90.80 µg/mL and ferruginol (IC 50 = 48.0 µg/mL) was identified to be the main active ingredient for the free radical scavenging [57]. In our study, the content of ferruginol was 3.94% in T. flousiana oil while the IC 50 value of the essential oil was 33.51 µg/mL. As a contrast, in the report of Ho et al. the content of ferruginol in T. cryptomerioides twig oil was 18.9% while the IC 50 value of the essential oils was 90.80 µg/mL [57]. In general, the antioxidant activity of essential oils is the product of additive, synergistic, and/or antagonistic effects from a complex mixture of several classes of compounds. These suggested that other components of the T. flousiana essential oil may possess the antioxidant activity. The biological functions of each component of the essential oil need to be further investigated.
Additionally, our results indicated that the main action site of the essential oil of T. flousiana might be the cell wall and chloroplast. Mechanism study plays a very important role in the development of new algicidal chemicals. Further mechanism studies should focus on cell wall and chloroplast.

Isolation of Essential Oil
The air-dried stem bark powder (250 g) of T. flousiana was subjected to hydrodistillation for 3 h using a Clevenger-type apparatus. The oil was dried with anhydrous sodium sulphate. The yield (v/w, dry weight basis) was calculated as volume (mL) of extracted essential oil per 250 g of plant material. Then, the essential oil was stored in hermetically sealed dark-glass at 4 • C until further analysis.

Analysis of the Essential Oil
Analysis of the essential oils was carried out with an Agilent Technologies 7693A Gas Chromatograph with 5977B Mass Spectrometer. A HP-5 MS capillary column (30 m × 0.25 mm × 0.25 µm; Agilent Technologies Inc., Santa Clara, USA) was employed. Analyses were carried out using helium as the carrier gas at a flow rate of 1.0 mL/min, split ratio: 15:1. Oven temperature was programmed as follows: 40 • C initially rising to 150 • C at a rate of 6 • C/min; rising to 270 • C at a rate of 3 • C/min; rising to 300 • C at a rate of 10 • C/min and held for 3 min. The injector and detector were held at 325 • C. The mixtures of the normal alkane of C 7 -C 30 (1000 µg/mL) and EO samples dissolved in hexane of 0.8 µL were injected and all samples were filtered through a 0.22 µm organic phase filter. The Mass spectra were obtained by electron ionization (EI) at 70 eV, using a spectral range of 30-550 AMU in full scan mode. The MS (Agilent Technologies Inc., Santa Clara, USA) transfer line was set at 250 • C.

Identification of the Essential Oil Chemical Constituents
The essential oil constituents identification was carried out by comparing their recorded mass spectra with those stored in the National Institute of Standards and Technology Mass Spectral database (NIST 17 database) or with authentic compounds and confirmed by comparison of their retention index with authentic compounds reported in the literature [58]. The relative percent of each component in essential oil was counted by the area normalization method. The retention index was defined by the following: where t n , t n + 1 , and t x were net retention times [59]. Identification of the individual components was based on: (i) Comparison with the mass spectra of authentic reference compounds possible and by reference to NIST 17 database, and Adams terpene library [43]; (ii) comparison of their retention indices (RI) on a HP-5, calculated relative to the retention times of a series of C-7 to C-30 n-alkanes, with linear interpolation, with those of authentic compounds or literature data [43].  [60].
The alga was cultured in 500 mL of sterilized culture medium in 1000 mL conical flasks under an irradiance of 4000 lux, 12 h light/12 h dark (12:12), at 25 ± 1 • C for 5 days. Then the 10 mL of the algal cultures (0.1 g) was transferred to a 6-well plate. The stock solution of the essential oil was prepared in acetone. The final concentrations of the essential oil in the test solution were 12.5, 25, 50, 100, and 200 µg/mL, respectively. Acetone in the test solution was lower than 0.2% (v/v). The commercial herbicide, butachlor (12.5, 25, 50, 100, and 200 µg/mL), was used as a control. The plates were sealed with polyethylene wrapping film and incubated in a growth chamber at 25 ± 1 • C, RH 50-60%, and a photoperiod of 12:12. Each treatment has three replicates. All experiments were repeated at least three times.
The algicidal activity was determined by the chlorophyll content as described by Dere et al. [61] with some modifications. Specifically, after being dried with absorbent paper, S. communis in each replicate was grounded in 2 mL of 80% acetone. Then the mixture was transferred into a centrifugal tube (2 mL) followed by centrifugation for 10 min at 4000 rpm. The supernatant was transferred into a tube and diluted with acetone to 4 mL. Then 2 mL of the solution was mixed with 80% acetone to make a final volume of 10 mL and the absorbances were recorded at 663 nm and 645 nm. Acetone (80%) alone was used for the blank control. The amount of the pigments was calculated according to the following formulas:

Evaluation of the Algicidal Activity without Light
The same method as described above in 4.5 was followed except the plates were incubated under a photoperiod of 24:0 (dark:light). The inhibition rate of chlorophyll was evaluated 96 h after the treatment. 200 µg/mL) on the ultra-structure of S. communis. The TEM samples were processed as previously described by Houot et al. [62]. Samples were examined by TEM (FEI Tecnai 12, FEI company, Hillsboro, USA).

Determination of Antimicrobial Effects of the Essential Oils on Mycelial Growth
Fungi including R. solani, C. gloeosporioiles, F. moniliforme, T. cucumeris, F. oxysporun f. sp. cubense, and D. bryoniae were obtained from the Department of Plant Pathology, South China Agricultural University. In vitro antifungal assays were conducted according to the method of Boubaker et al. [63], with slight modifications. Briefly, sterile molten potato-dextrose-agar (PDA) supplemented with essential oil of T. flousiana, at final concentrations of 62.5, 125, 250, 500, and 1000 µg/mL, was poured into Petri plates (6-cm-diameter). All tests were performed in PDA supplemented with 0.5% (v/v) DMSO to enhance oil solubility. Afterwards, plates were inoculated with fungal cultures with 5-mm diameter agar disks from one-week-old cultures, with mycelia surface facing down. The agar plates were then incubated at 25 • C for 2 days. Plates with medium supplemented with 0.5% DMSO only was used as the control. The antifungal activity was expressed as percent of mycelial radial growth inhibition and calculated according to the following formula: MGI (%) = ((C − T)/C) × 100, where C and T represent mycelial growth diameter in control and EO treated plates, respectively. Each treatment has three replicates. All experiments were repeated at least three times.
The in vitro antibacterial activity of the essential oil from T. flousiana was carried out by using filter paper disc diffusion assay [64,65]. Two Gram-positive bacteria S. aureus and B. subtilis and two Gram-negative bacteria E. coli and R. solanacearum, provided by the Department of Plant Pathology, South China Agricultural University, were tested. Typically, 500 µl of a suspension of the tested microorganisms (approx. 10 6 colony-forming units (CFU)/mL) was spread with a sterile cotton swab on the surface of Mueller-Hinton agar (MHA) plates at 37 • C and allowed to dry for 10 min. A stock solution of the essential oil was prepared by dissolving 20 mg in 1 mL of DMSO. Then the stock solution was diluted with 0.1% aqueous Tween solution to get series solution of 4000, 3000, 2000, 1000, and 500 µg/mL. Each sterile filter paper disc (6 mm in diameter Whatman disks) was impregnated with 10 µL solutions, respectively. The Petri dishes were kept at 4 • C for 2 h to allow the diffusion of the oil, and further incubated at 37 • C for 24 h. Activity was expressed as percent of zone of inhibition (ZOI, mm). The net zone of inhibition was determined by subtracting the disc diameter (i.e., 6.0 mm) from the total zone of inhibition shown by the test disc in terms of clear zone around the disc. The control was the aqueous solution of 0.1% Tween + 8% DMSO. Each treatment had three replicates. All experiments were repeated at least three times.

Determination of Antioxidant Activity
The method of El-Gawad [66] was used. The antioxidant activity of T. flousiana essential oil was measured in terms of radical scavenging activity, using the stable radical DPPH (Sigma-Aldrich, Darmstadt, Germany) [48]. A reaction mixture of 1 mL of a hexane solution of the essential oil with different concentrations (5,10,20,40, and 80 µg/mL) and equal volume of the methanolic solution of 0.3 mM DPPH was prepared, mixed well and incubated under dark condition for 15 min at room temperature. Ascorbic acid (5,10,20,40, and 80 µg/mL) was used as the reference. The decrease in absorbance at 517 nm was determined using a spectrophotometer (UV-8500PC, Shanghai, China). The IC 50 (the amount of sample necessary to decrease the absorbance of DPPH by 50%) was calculated graphically. Each treatment has three replicates. All experiments were repeated at least three times. The percent of the inhibition of the DPPH radical was calculated as following: The inhibition (%) = 1 − (Absorbance of sample/Absorbance of control) × 100 (7)

Statistical Analysis
Statistical analysis (ANOVA) by means of the IBM SPSS Statistics, Version 19.0 (International Business Machines Corporation, New York, USA) was applied to the data to determine the differences (p < 0.05). Then, the estimation of the median effective concentration (EC 50 ), median inhibition concentration (IC 50 ), and their 95% confidence limits were obtained. All quantitative data were presented as the mean ± SD of at least three independent experiments using the Duncan's multiple range test or Student's t test for group differences. A p < 0.05 was considered as statistically significant.
The algicidal activity of the essential oil on S. communis was comparable to that of butachlor. The IC 50 values of the essential oil ranged from 31.77 to 84.92 µg/mL, while the IC 50 values of butachlor ranged from 40.24 to 58.09 µg/mL. Thus the essential oil from T. flousiana could be considered as a potential algicidal substitute of synthetic ones. In addition, ultrastructure changes revealed by the transmission electron microscopy indicated that the main action sites of the essential oil of T. flousiana on S. communis cell were the chloroplast and cell wall.
The level of antioxidant activity estimated by 2,2-diphenyl-1-picrylhydrazyl (DPPH) method showed that the essential oil of T. flousiana demonstrated obvious antioxidant activity with IC 50 value of 33.51 µg/mL. While the IC 50 value of the positive control ascorbic acid was 7.98 µg/mL. Thus, the essential oil of this plant could be used as a potential source of natural bioactive molecules in agrochemical industry as well as in food and cosmetic industries.