Bangladesh J Pharmacol. 2016; 11: 269-280 |
Available Online: 29 January 2016 | DOI: 10.3329/bjp.v11i1.25487 |
Chemical characterization and mode of action of Ligustrum lucidum flower essential oil against food-borne pathogenic bacteria
Vivek K. Bajpai1, Siddhartha Singh2 and Archana Mehta2
1Department of Applied Microbiology and Biotechnology, School of Biotechnology, Yeungnam University, Gyeongsan, Gyeongbuk 712 749, Republic of Korea; 2Department of Botany, Dr. Hari Singh Gour University, Sagar 470 003, Madhya Pradesh, India.
Current research analyzes the chemical composition of Ligustrum lucidum flower essential oil obtained by the hydrodistillation, and examines its anti-microbial mode of action against food-borne pathogenic bacteria. Gas chromatography-mass spectrometry analysis of the oil resulted in the determination of 44 different compounds, representing 85.2% of the total oil. The oil (1 mg/disc) showed significant antibacterial effect as diameters of inhibition zones (14.6 ± 0.2 – 19.7 ± 0.3 mm), as well as minimum inhibitory and minimum bactericidal concentrations values (250–1000 and 250–2000 µg/mL), respectively. Based on the susceptibility, L. lucidum flower oil revealed its mode of action on membrane integrity as confirmed by increased release of extracellular ATP (2.5 and 2.2 pg/mL), leakage of potassium ions (950 and 900 mM/L), loss of 260-nm absorbing materials (4.2 and 3.9 optical density), and increase in relative electrical conductivity (10.6 and 9.8%) against Staphylococcus aureus KCTC-1621 (Gram-positive) and Salmonella enterica ATCC-4731 (Gram-negative), respectively.
There has recently been considerable concern with the increasing incidence of food-borne diseases, which have become relevant public health issues (Oussalah et al., 2007; da Silveira et al., 2012). In spite of the advances in the sanitation techniques and inspection services, the contamination of foods with undesirable micro-organisms is a potential risk during food processing, re-processing, storage and distribution both in developing and developed countries (Runyora et al., 2010).
Although synthetic preservatives have shown remarkable effectiveness as antimicrobials, they might be detrimental to human health (Aiyelaagbe et al., 2007). Hence, application of essential oils as safe and effective alternatives to synthetic preservatives in controlling pathogenic bacteria may able to reduce the risk of food-borne outbreaks and may assure consumers with safe and microbially-contaminated free food products (Yoon et al., 2011).
Ligustrum lucidum is a species of privet (Ligustrum genus), a flowering plant in the olive family, Oleaceae, native to the southern half of China and naturalized in several other countries including Spain, Italy, Japan, and Korea. The seeds of L. lucidumare known to use in traditional Chinese medicine (Chen, 2012). In studies of laboratory animals, the herbal extracts derived from L. lucidum have been shown to have anti-inflammatory, anti-diabetic, anti-hyperlipidemic, and hepatoprotective properties (Chen, 2012). However, not much research has been focused on the floral parts of L. lucidum.
Present study characterizes the chemical composition of essential oil isolated from the floral parts of L. lucidum and evaluates its antimicrobial mode of action against food-borne pathogenic bacteria.
Collection of sample and oil preparation
The flowers of L. lucidum were collected in March 2015 from the local area of Gyeongsan City, Gyeongbuk, Republic of Korea, and identified by the taxonomist and the data-base present at the Department of Applied Microbiology and Biotechnology, Yeungnam Univer-sity, Korea. A voucher specimen has been deposited in the herbarium of Laboratory of Microbiology, under the number (DPT/Herb/2015-15). The flowers were dried, powdered and passed through 40-mesh sieve and stored in an airtight container for further use. The powdered flower material (100 g) was subjected to hydrodistillation for 3 hours, using a Clevenger apparatus. The oil was dried over anhydrous Na2SO4 and preserved in an airtight vial at low temperature (4°C) for further analysis.
Gas chromatography-mass spectrometry (GC-MS) analysis
A detailed chemical composition analysis of flower essential oil of L. lucidum was performed using a GC/MS (Jeol JMS 700 GC-MS spectrometer) equipped with an Agilent 6890N GC DB-5 MS fused silica capillary column (30 m × 0.25 m i.d., film thickness 0.25 μm). For GC-MS detection, an electron ionization system with ionization energy of 70 eV was used. Helium gas was used as the carrier gas at a constant flow rate of 1 mL/min. Injector and MS transfer line temperature were set at 280 and 250°C, respectively. The initial oven temperature of 50°C was maintained for 2 min, and then increased to 250°C at a rate of 10°C/min followed by holding at 250°C for 10 min. Diluted samples (1/100, v/v, in methanol) of 1.0 μL were injected manually in the split-less mode. The relative percentage of the oil constituents was expressed as percentages by peak area normalization. Identification of essential oil components was based on GC retention time on a DB-5 capillary column relative to computer matching of mass spectra using Wiley and NIST libraries for the GC-MS system.
Microorganisms
The test food-borne pathogens included Staphylococcus aureus KCTC-1621, Bacillus subtilis KCTC-3569, Listeria monocytogenes KCTC-3569, Salmonella enterica ATCC-4731 and Escherichia coli O157:H7. All the bacterial strains were grown in the nutrient broth (NB) at 37°C. The bacterial strains were maintained on nutrient agar slants at 4°C.
Determination of antibacterial activity by disc diffusion assay
Standard agar diffusion method was used for the determination of antibacterial efficacy of flower essential oil of L. lucidum (Bajpai et al., 2013). Petri-plates were prepared by pouring 20 mL of nutrient agar medium and allowed to solidify. Plates were dried and 1 mL of standardized inoculum containing 107 CFU/mL of bacterial suspension was poured and uniformly spread, and the inoculum was allowed to dry for 5 min. A Whatman No. 1 sterile filter paper disc (6 mm diameter) was impregnated with 1 mg/disc of flower oil of L. lucidum. The oil was dissolved in 5% dimethyl sulfoxide (DMSO). Negative controls were prepared using DMSO. Standard reference tetracycline (25 µg/disc) was used as a positive control against the tested bacteria. The plates were incubated at 37°C for 24 hours. Antibacterial activity was evaluated by measuring the diameters of inhibition zones against the tested bacteria. Each assay in this experiment was performed in triplicate.
Determination of minimum inhibitory and minimum bactericidal concentrations
The minimum inhibitory concentration (MIC) of flower essential oil of L. lucidum was tested by two-fold serial dilution method (Bajpai et al., 2013). The oil was first dissolved in DMSO and incorporated into nutrient broth (NB) medium for bacterial pathogens to obtain a concentration of 2000 µg/mL, and serially diluted to achieve 1,000, 500, 250, 125, 62.5, 31.25, 15.62 and 7.81 µg/mL, respectively. A 10 µL standardized suspension of each tested organism (approximately 107 CFU/mL) was transferred to each tube. The control tubes containing only bacterial suspensions were incubated at 37°C for 24 hours. The lowest concentration of oil, which did not show any visible growth of test organisms after macroscopic evaluation, was determined as MIC. Further, the concentrations showing complete inhibition of visual growth of bacterial pathogens were identified, and 50 µL of each culture broth was transferred on to the agar plates and incubated for specified time and temperature as mentioned above. The complete absence of growth of bacterial colonies on the agar surface was the lowest concentration of sample and was defined as the minimum bactericidal concentration (MBC). Each assay in this experiment was replicated three times. A visual demonstration of this assay has been given in attached video content.
Effect on viable counts of bacterial pathogens
Based on the susceptibility of bacterial pathogens used in this study, two strains S. aureus KCTC-1621 (Gram-positive) and S. enterica ATCC-4731 (Gram-negative) were selected for further studies. Active cultures for viable count assay were prepared in NB broth medium, grown at 37°C for 24 hours. For each strain, 1 mL of active stock solution (approximately 107 CFU/mL) was transferred to 2 mL of Eppendorf tube. The cultures were then centrifuged at 10,000 rpm for 10 min. The pellets were retained and re-suspended with 1 mL of phosphate-buffered saline (PBS). For viable counts, each of the tubes containing re-suspended bacterial suspension (approximately 107 CFU/mL) of S. aureus KCTC-1621 and S. enterica ATCC-4731 was inoculated with 100 µL oil at MIC concentration in 900 µL NB broth, and kept at 37°C. Samples for viable cell counts were taken out at 0, 40, 80, 120, 160 and 200 min time intervals. The viable plate counts were monitored as followed: after incubation, 100 µL of the re-suspended culture was diluted into 900 µL PBS, there by diluting it 10-fold. A 100 µL sample of each treatment was diluted and spread on the surface of NB agar. The colonies were counted after 24 hours of incubation at 37°C (Bajpai et al. 2013). The controls were inoculated without oil for each bacterial strain with same experimental condition as mentioned above. Each assay in this experiment was replicated three times.
Measurement of extracellular adenosine 5’-triphophate (ATP) concentration
To determine the efficacy of L. lucidum flower oil on membrane integrity, the extracellular ATP concentrations were measured according to our previously described method (Bajpai et al., 2013). The working cultures of S. aureus KCTC-1621 and S. enterica ATCC-4731 containing approximately 107 CFU/mL inoculum were centrifuged for 10 min at 1,000 xg, and the supernatants were removed. The cell pellets were washed three times with 0.1 M of sodium phosphate buffer (pH 7.0) and then cells were collected by centrifugation for 10 min at 1,000 xg. A cell suspension (107 CFU/mL) was prepared with 9 mL of sodium phosphate buffer (0.1 M; pH 7.0) and 0.5 mL of cell solution was taken into the Eppendorf tube for the treatment of L. lucidum flower oil. Then, the different concentrations (control and MIC) of L. lucidum flower oil were added to the cell solution. Samples were maintained at room temperature for 30 min, centrifuged for 5 min at 2,000 xg, and incubated in ice immediately to prevent ATP loss until measurement. The extracellular (upper layer) ATP concentrations were measured using an ATP bioluminescent assay kit (Sigma, USA) which comprised ATP assay mix containing luciferase, luciferin, MgSO4, dithiothreitol (DTT), ethylenediamine tetraacetic acid (EDTA), bovine serum albumin (BSA) and tricine buffer salts. The ATP concentration of the supernatants, which represented the extracellular concentration, was determined using a luminescence reader after the addition of 100 µL of ATP assay mix to 100 µL of supernatant. The emission and excitation wavelengths were 520 and 420 nm, respectively.
Assay of potassium ions efflux
Our previously described method was used to determine the amount of the potassium ions (Bajpai et al., 2013). The concentration of free potassium ions in bacterial suspensions of S. aureus KCTC-1621 and S. enterica ATCC-4731 was measured after the exposure of bacterial cells to L. lucidum flower oil at MIC concentration in sterile peptone water for 0, 30, 60 and 120 min. At each pre-established interval, the extracellular potassium concentration was measured by a photometric procedure using the calcium/potassium kit. Similarly control was also tested without adding L. lucidum flower oil. Results were expressed as amount of extracellular free potassium (mM) in the growth media in each interval of incubation.
Measurement of release of 260-nm absorbing cellular materials
The measurement of the release of 260-nm-absorbing materials from S. aureus KCTC-1621 and S. enterica ATCC-4731 cells was carried out in aliquots of 2 mL of the bacterial inocula in sterile peptone water (0.1 g/100 mL) added of L. lucidum flower oil MIC concentration at 37°C. At 0, 30 and 60 min time interval of treatment, cells were centrifuged at 3,500 xg, and the absorbance of the obtained supernatant was measured at 260 nm using a 96-well plate ELISA reader (Bajpai et al., 2013). Similarly control was also tested without adding L. lucidum flower oil. Results were expressed in terms of optical density of 260-nm absorbing materials in each interval with respect to the ultimate time.
Measurement of cell membrane permeability
Effect of L. lucidum flower oil on cell membrane permeability of test microorganism was determined as described previously (Patra et al., 2015) and expressed in terms of relative electrical conductivity. Prior to the assay, cultures of test microorganisms were incubated at 37°C for 10 hours, followed by centrifugation (5,000 xg) for 10 min, and washed with 5% glucose solution (w/v) until their electrical conductivities reached close to 5% glucose solution to induce an isotonic condition. Minimum inhibitory concentrations of L. lucidum flower oil acquired for both the test organisms were added to 5% glucose (isotonic solution), incubated at 37°C for 8 hours, and the electrical conductivities (La) of the reaction mixtures were determined. Further, electrical conductivities of the bacterial solutions were measured at 2 hours of intervals for a total duration of 8 hours (Lb). The electrical conductivity of each test pathogen in isotonic solution killed by boiling water for 5 min served as a control (Lc). The relative electrical conductivity was measured using an electrical conductivity meter. The permeability of bacteria membrane was calculated according to the following formula:
Relative conductivity (%) = La – Lb / Lc x 100
Statistical analysis
All data are expressed as the mean ± SD by measuring three independent replicates. Analysis of variance using one-way ANOVA followed by Duncan's multiple test to test the significance of differences at the level of 0<0.05 using a SAS software.
Chemical composition of L. lucidum flower oil
The GC-MS analysis of the L. lucidum flower oil led to the identification of 44 different components represent-ting 85.2% of the total oil. The hydrodistillation of L. lucidum flower yielded light yellowish oil with the major composition of the oil containing oxygenated mono- and sesquiterpenes and their aromatic hydrocarbons along with some other essential phytochemicals. As shown in Table I, the major components of L. lucidum flower essential oil were identified to be styrene glycol (26.6%), formic acid (14.6%), capsaicin (2.9%), 4-propoxy-2,5-dimethoxy amphetamine (2.8%), falcarinol (2.8%), 3,4-epoxyguai-1(10)–en-6,12-olide (2.6%), 7-O-methyl-3-desoxy-norreticuline (2.5%), 2,3-dihydrobenzofuran (2.3%), homofascaplysin C (2.2%), elymoclavine (1.8%), uvidin B (1.7%), aspidofractinine-3-methanol (1.5%) and 2-dinitrophenyl sulphone (1.4%). The essential oil composition of L. lucidum flower has not been reported before and therefore, our results can be considered as the first report on the essential oil composition of L. lucidum.
No. | RT (min) | Compound | Composition (%) | Identification |
---|---|---|---|---|
1 | 1.52 | Formic acid | 14.58 | EI-MS |
2 | 5.31 | 1-N-Methyluracil | 0.66 | EI-MS |
3 | 6.1 | 2-Phenylimidazoline | 0.67 | EI-MS |
4 | 6.18 | 2-Ethylmalonimide | 0.44 | EI-MS |
5 | 6.38 | 5-Ethyl-1H-indene | 0.95 | EI-MS |
6 | 7.48 | 2, 3-Dihydrobenzofuran | 2.3 | EI-MS |
7 | 7.56 | 4-Mercaptophenol | 0.73 | EI-MS |
8 | 8.73 | Acetovanillone | 0.75 | EI-MS |
9 | 8.86 | Durenol | 0.84 | EI-MS |
10 | 9.56 | 8-Azaisochroman-1, 4-dione | 0.39 | EI-MS |
11 | 9.96 | Tryptophol acetate | 0.69 | EI-MS |
12 | 10.39 | Styrene glycol | 26.63 | EI-MS |
13 | 10.83 | Falcarinol (Z) | 2.77 | EI-MS |
14 | 10.96 | 1,2,3,4-Tetrahydro-7-chlorobenz [c] acridine | 0.53 | EI-MS |
15 | 11.19 | Fucitol-1-D-2, 3, 4-trimethyl-1, 5-diacetate | 0.61 | EI-MS |
16 | 11.72 | Ethyl homovanillate | 0.56 | EI-MS |
17 | 11.87 | 5-Propyl guaiacol | 0.91 | EI-MS |
18 | 12.06 | Cassie ketone | 0.88 | EI-MS |
19 | 12.46 | Caproic acid | 0.68 | EI-MS |
20 | 12.79 | 3, 4-Mpoxyguai-1 (10) - en-6, 12-olide | 2.63 | EI-MS |
21 | 12.87 | Megastigmatrienone 2 | 0.84 | EI-MS |
22 | 13.14 | Ethyltributylstannane | 0.88 | EI-MS |
23 | 13.21 | 2-Dinitrophenyl sulphone | 1.39 | EI-MS |
24 | 13.42 | Homofascaplysin C | 2.24 | EI-MS |
25 | 13.51 | Elymoclavine | 1.81 | EI-MS |
26 | 14.11 | Capsaicin | 2.86 | EI-MS |
27 | 14.27 | Isopropyl myristate | 0.58 | EI-MS |
28 | 14.62 | Uvidin B | 1.72 | EI-MS |
29 | 15.07 | 7-O-methyl-3-desoxy-norreticuline | 2.46 | EI-MS |
30 | 15.32 | 1-Methylinosine | 0.72 | EI-MS |
31 | 15.97 | Methyl palmitate | 0.66 | EI-MS |
32 | 16 | Weberine | 0.62 | EI-MS |
Antibacterial activity
The antibacterial activity of L. lucidum flower oil against the tested food-borne pathogenic bacteria was qualitatively and quantitatively determined by the presence or absence of inhibition zones. As presented in Table II, the oil (1 mg/disc) exhibited potent inhibitory effect against the tested food-borne pathogenic bacteria. In this assay, Gram-positive bacteria such as S. aureus KCTC-1621, B. subtilis KCTC-3569 and L. monocytogenes KCTC-3569 were found to be the most inhibited bacterial pathogens by L. lucidum flower oil with their respective diameters of inhibition zones of 19.7 ± 0.3, 18.3 ± 0.2 and 17.2 ± 0.2 mm, whereas Gram-negative bacteria including S. enterica ATCC-4731 and E. coli O157:H7 were inhibited moderately with diameters of inhibition zones of 15.2 ± 0.2 and 14.6 ± 0.2 mm, respectively (Table II). In this assay, L. lucidum flower oil exhibited significant (p<0.05) antibacterial effect when compared with standard drug tetracycline at the used concentration. The diameters of inhibition zones of L. lucidum flower oil against Gram-positive bacteria were found to be higher than Gram-negative bacteria (Table II). The DMSO, as a negative control had no inhibitory effect at the used concentration.
Minimum inhibitory and bactericidal concentrations
L. lucidum flower oil showed potent inhibitory effect as MIC and MBC values against all the tested food-borne pathogenic bacteria. As shown in Table II, the MIC and MBC values of L. lucidum flower oil against the tested Gram-positive bacteria of S. aureus KCTC-1621, B. subtilis KCTC-3569 and L. monocytogenes KCTC-3569 were found in the range of 250 to 500 µg/mL, while for Gram-negative bacteria such as S. enterica ATCC-4731 and E. coli O157:H7, the MIC and MBC values were found in the range of (1 mg/mL for each bacterial pathogen) and (1-2 mg/mL), respectively. In this assay, S.aureus KCTC-1621, B. subtilis KCTC-3569 and L. monocytogenes KCTC-3569 were found extremely susceptible pathogens to L. lucidum oil with MIC and MBC values of (250, 250 and 500 µg/mL) and (250, 500 and 500 µg/mL), respectively. However, in this study, both Gram-positive and Gram-negative bacteria were found susceptible to L. lucidum flower oil (Table II).
Pathogens | Essential oil from the floral parts of Ligustrum lucidum | |||
---|---|---|---|---|
Diameters of inhibition zones (mm) | Susceptibility | |||
Essential oil | Tetracyclinc | MIC | MBC | |
Staphylococcus aureus KCTC-1621 | 19.66 ± 0.33 | 24.22 ± 0.05 | 250 | 250 |
Bacillus subtilis KCTC-3569 | 18.33 ± 0.24 | 26.27 ± 0.07 | 250 | 500 |
Listeria monocytogenes KCTC-3569 | 17.23 ± 0.22 | 27.10 ± 0.02 | 500 | 500 |
Salmonella enterica ATCC-4731 | 15.21 ± 0.21 | 15.53 ± 0.04 | 1,000 | 1,000 |
Escherichia coli O157:H7 | 14.62 ± 0.17 | 16.42 ± 0.07 | 1,000 | 2,000 |
Effect on cell viability
Based on the sensitivity of the test food-borne pathogens, one Gram-positive (S. aureus KCTC-1621) and a Gram-negative (S. enterica ATCC-4731) bacteria were selected as the model organisms for further studies to confirm the antibacterial mode of action of L. lucidum flower essential oil. In this regard, further study was carried out to evaluate the effect of L. lucidum oil on the viable counts of the selected bacteria such as S. aureus KCTC-1621 and S. enteric ATCC-4731. The effect of L. lucidum oil on the growth of tested bacterial pathogens demonstrated reduced viability at the used concentration (Figure 1). Exposure of 0 to 80 min of L. lucidum flower oil did not cause severe decline on the inhibition of cell viability of the tested pathogens, however, considerable amount of inhibitory effect was observed on the inhibition of the cell viability of the tested bacteria of S. aureus KCTC-1621 and S. enterica ATCC-4731 at the exposure time of 120 and 160 min, respectively. Interestingly, the exposure of L. lucidum oil for 120 min revealed complete inhibition of colony forming unit (CFU) numbers against S. aureus KCTC-1621 (Figure 1a). On the other hand, complete inhibition of cell viable counts of S. enterica ATCC-4731 was observed at 160 min exposure time of L. lucidum oil, and no CFU formation was observed (Figure 1b).
Measurement of ATP
The effect of L. lucidum seed oil on the determination of extracellular ATP concentrations in S. aureus KCTC-1621 and S. enterica ATCC-4731 cells is presented in Figure 2. The extracellular ATP concentrations in the control cells S. aureus KCTC-1621 and S. enterica ATCC-4731 were found to be 0.8 and 0.4 pg/mL, respectively (Figure 2). S. aureus KCTC-1621 and S. enterica ATCC-4731 cells treated with L. lucidum flower oil at MIC concentration showed significant (p<0.05) increase in the release of extracellular ATP concentration. In this assay, the extracellular ATP concentrations for S. aureus KCTC-1621 and S. enterica ATCC-4731 cells were measured to be 2.5 (Figure 2a) and 2.2 (Figure 2b) pg/mL, respectively.
Measurement of potassium ion leakage
In this assay, antibacterial mode of action of L. lucidum flower oil was confirmed by the release of potassium ions from the treated cells of S. aureus KCTC-1621 and S. enteric ATCC-4731 (Figure 3). The release of potassium ions from the bacterial cells occurred immediately after the addition of L. lucidum flower oil at MIC concentration following a sturdy loss along the specified time period (Figure 2). However, no leakage of potassium ion was observed in control cells of S. aureus KCTC-1621 and S. enterica ATCC-4731 during the study (Figure 3).
Measurement of 260 nm materials
Further, antibacterial mode of action of L. lucidum flower oil was visualized by the confirmation on the leakage of 260 nm absorbing materials when the test food-borne pathogens exposed to L. lucidum flower oil at MIC. In this assay, exposure of S. aureus KCTC-1621 and S. enterica ATCC-4731 to L. lucidum flower oil caused rapid loss of 260-nm absorbing materials from the bacterial cells. The optical density (260 nm) of the culture filtrates of S. aureus KCTC-1621 and S. enterica ATCC-4731 cells exposed to L. lucidum flower oil revealed an increasing release of 260 nm absorbing materials with respect to exposure time Figure 4. However, no changes in the optical density of control cells of test pathogens were observed during the study. After 60 min of treatment, approximately more than 2-fold increase was observed in the optical density of the bacterial cell culture filtrates treated with L. lucidum flower oil (Figure 4).
Measurement of cell membrane permeability
Figure 5 demonstrates the effect of MIC exposure of L. lucidum flower oil on the membrane permeability of S. aureus KCTC-1621 and S. enterica ATCC-4731 in terms of their relative electrical conductivities. L. lucidum flower oil exhibited time-dependent effect in this assay, and the relative electrical conductivity of each test pathogen was increased timely. However, flower oil exerted significantly (p<0.05) higher effect on S. aureus KCTC-1621 (Figure 5a) with increased proportion of relative electrical conductivity as compared to S. enterica (Figure 5b). No relative electrical conductivity was observed in untreated samples as a control.
The results of the antibacterial screening showed that L. lucidum flower oil had strong and consistent inhibitory effect against the tested food-borne pathogens as confirmed by the inhibitory effect of L. lucidum flower oil showing different susceptibility rate against the tested food-borne pathogens.
Essential oils are volatile and odorous principles of plant secondary metabolism which have wide applications in food flavoring and preservation industries (Bajpai et al., 2012). In recent years, several researchers have reported that mono-terpene or sesquiterpene hydrocarbons and their oxygenated derivatives, which are major components of essential oils, exhibit potential antimicrobial activity (Cakir et al., 2004). These findings strongly support the outcomes of this study as L. lucidum flower oil was also found to contain oxygenated sesquiterpenes and their respective hydrocarbons, confirming its efficacy as natural antimicrobial agent.
Furthermore, the results from viable count assay revealed that exposure of L. lucidum flower oil had a rigorous effect on the cell viability of the tested bacterial pathogens. L. lucidum flower oil exerted its maximum bactericidal activity as evident by the significant reduction in microbial counts and complete inhibition of S. aureus KCTC-1621 and S. enterica ATCC-4731 cell viable counts at the exposure time of 120 and 160 min, respectively. Previously we confirmed the inhibitory effects of various plant-based essential oils on the cell viability of food-borne pathogenic bacteria (Bajpai et al., 2012; Bajpai et al., 2013; Bajpai et al., 2015). Similar to our findings, other essential oils also exerted inhibitory effects against various food-borne pathogens (Al-Reza et al., 2010).
Further, in this study, membrane permeability parameters such as determination of extracellular ATP concentration, leakage of potassium ions, loss of 260 nm absorbing materials, and measurement of relative electrical conductivity were used to determine the mode of action of L. lucidum flower oil against selected food-borne pathogenic bacteria. It was confirmed that L. lucidum flower oil had detrimental effect on damaging cell membrane integrity, resulting in the increased extracellular ATP concentration from the treated cells. The use of ATP has been confirmed in various cell functions including transport work moving substances across cell membranes which might be an important parameter to understand the mode of action of antibacterial agents.
The results of our study on the determination of extracellular ATP concentration showed an increasing rate of extracellular ATP concentrations after S. aureus KCTC-1621 and S. enteric ATCC-4731 cells exposed to L. lucidum flower oil. This phenomenon may lead to significant impairment in membrane permeability of the tested bacteria by L. lucidum flower oil, which caused the intracellular ATP leakage through defective cell membrane as also reported previously (Bajpai et al., 2013). It has been found that cells of B. subtilis treated with essential oil components resulted in the release of increased level of extracellular ATP pool (Helander et al., 1998). Subsequently, the antibacterial effect might be established because of proton motive force inhibition, mitochondrial respiratory inhibition, inhibition of substrate oxidation and active transportation, and loss of pool metabolites, as well as disruption of synthesis of macromolecules, proteins, lipids and polysaccharides may also occur. In general, leakage of intracellular material is induced by many antimicrobial agents resul-ting in the death of a cell (Denyer, 1990; Farag et al., 1989).
Moreover, in this study, L. lucidum flower oil exerted remarkable efficacy on the release of potassium ions from the treated cells of S. aureus KCTC-1621 and S. enterica ATCC-4731 cells at MIC concentration. The bacterial plasma membrane provides a permeability barrier to the passage of small ions such as potassium ions which are necessary electrolytes, facilitating cell membrane functions and maintaining proper enzyme activity. This impermeability to small ions is regulated by the structural and chemical composition of the membrane itself. Increases in the leakage of potassium ions could be an indication of disruption of this permeability barrier.
Maintaining ion homeostasis is integral to the maintenance of the energy status of the cell including solute transportation, regulation of metabolism, control of turgor pressure and motility (Cox et al., 2001). Therefore, even relatively slight changes to the structural integrity of cell membranes can severely affect cell metabolism and lead to cell death, and potassium ion efflux (Cox et al., 2001).
Measurement of specific cell leakage markers such as 260 nm absorbing materials is an indication of membrane sensitivity to specific antimicrobial agent in relationship to control cells. In this study, L. lucidum flower oil exhibited significant potential on the release of 260 nm materials (DNA and RNA) from the cells of tested bacteria when exposed to MIC concentration. This directly indicates the confirmation of leakage of 260 nm absorbing materials from the bacterial cells treated with L. lucidum flower oil. The observation that the amount of loss of 260 nm absorbing materials was as extensive as the leakage of potassium ions might indicate that the membrane structural damage sustained by the bacterial cells resulted in release of macromolecular cytosolic constituents (Farag et al., 1989). The effect of carvacrol, an essential oil component, on bacterial proton motive force was strongly correlated to the leakage of various substances, such as ions, ATP, nucleic acids and amino acids (Herranz et al., 2001). This suggested that monitoring K+ efflux and release of 260 nm absorbing materials from S. aureus KCTC-1621 and S. enterica ATCC-4731 might be more sensitive indicators of membrane damage and loss of membrane integrity (Cox et al., 2001).
Furthermore, this study revealed that L. lucidum flower oil has ability to disrupt the plasma membrane as confirmed by the changes observed in the relative electrical conductivity of both the tested bacteria. Similarly oil from different plant origin has also shown the remarkable effect on relative electrical conductivity parameters of food-borne pathogens (Patra et al., 2015). Maintaining membrane permeable integrity is essential for overall metabolism of a bacterial cell, hence, changes in the relative electrical conductivity on membrane integrity may severely hamper the cell metabolism, which may eventually lead cell death (Cox et al., 2001). Based on the findings of this study, we hypothesized an antibacterial mechanism of action of L. lucidum flower oil that accumulation of the oil in the plasma membrane caused instant loss of the cell integrity and became increasingly more permeable to ions and other essential metabolites that might be the reason for the establishment of the antibacterial activity of L. lucidum flower oil. Excessive leakage of cytoplasmic material is used as indication of gross and irretrievable damage to the plasma membrane (Cox et al., 1998).
Moreover, some essential oils exert greater inhibitory effect against broad-range of pathogenic microorganisms. However, in this study, the Gram-positive bacteria were found to be more susceptible to the L. lucidum flower oil than Gram-negative bacteria. The hydrophilic cell wall structure of Gram-negative bacteria is constituted essentially of lipopolysaccharide that blocks the penetration of hydrophobic components and avoids the accumulation of essential oils in target cell membrane (Bezic et al., 2003). The single membrane of Gram-positive bacteria is considerably more accessible to permeation by hydrophilic components of essential oil in the target sites. This might be the reason that Gram-positive bacteria were found to be more sensitive to the L. lucidum flower oil than those of Gram-negative bacteria. Similar findings on the susceptibility of various essential oils against food-borne pathogenic bacteria including Gram-positive and Gram-negative bacteria have been reported previously (Bajpai et al., 2012; Bajpai et al., 2013).
The results of this study indicate that the L. lucidum flower essential oil is able to disrupt membrane functions of both Gram-positive and Gram-negative bacteria. Hence, we conclude that L. lucidum flower oil exerts its inhibitory effect through permeabilization of the cell membrane associated with generalized membrane-disrupting effects, and this corresponds to a simultaneous reduction in the number of viable bacteria, loss of 260 nm absorbing materials, and leakage of potassium ions with decreased pool of extracellular ATP and increase in relative electrical conductivity being indicative of loss of membrane integrity.
L. lucidum flower oil showing significant antibacterial activity, can be used as a natural antimicrobial agent in food and pharmaceutical industries to combat against food-borne pathogens.
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