1. IntroductionAmong the dematiaceous fungi responsible for human or animal phaeohyphomycosis, the Exophiala genus is a well-known etiologic agent that presently includes several species considered as opportunistic pathogens [1-3]. In recent years, Exophiala fungi have been repeatedly reported as root-associated endophytic fungi, which have also been designated as dark septate endophytes (DSEs) [4,5]. Under low-power light microscopy, their pigmented structures, including dematiaceous septate hyphae and microsclerotia (aggregation of dark, thick-walled, and closely packed inflated cells), are easily visible colonizing the root cortex, the epidermis, and root surfaces intercellularly and intracellularly [6-8]. More data from field studies reveal that DSE comprise ascomycetous fungi which have a ubiquitous distribution and wide range of host plants [9,10] and they are especially common in stressful environments [11,12]. Previous studies in our laboratory found that most plants that naturally developed in a Pb–Zn slag heap in Southwest China are commonly colonized by DSEs [13] and DSEs isolated from these areas possess an inherent tolerance to heavy metals [14]. Under metal-polluted soils, the metal tolerant DSE strain Exophiala pisciphila H93 clearly alleviated the deleterious effects of excessive heavy metal ions and its colonization improved the metal tolerance of maize [15].
Zinc is an essential micronutrient required for a wide variety of cellular processes. However, excessive Zn can be toxic to organisms [16], which is proposed in the 13 metal contamination list by the US Environmental Protection Agency (US EPA) [17]. Excessive heavy metals are known to induce oxidative stress by generating high concentrations of reactive oxygen species (ROS), such as superoxide radical, hydroxyl radical (HO•), and hydrogen peroxide (H2O2), and affect the activity of endogenous enzymes, or membrane polyunsaturated fatty acids, which leads to lipid peroxidation and malondialdehyde (MDA) formation [18,19]. Thus, MDA is considered as a cytotoxic product of lipid peroxidation and an indicator of free radical production and consequent tissue damage. If they are not effectively neutralized by the antioxidant defense system in tissues, oxidative stress results in direct damage to lipids, proteins, and DNA, and eventually initiates cell damage [20,22]. The antioxidant defense system of organisms is composed of different antioxidant components, including a non-enzymatic antioxidant system, e.g., carotenoids, ascorbate, and glutathione (GSH), and an enzymatic anti-oxidative system, e.g., total superoxide dismutase (T-SOD), catalase (CAT), and peroxidase (POD) [23-25]. Under abnormal circumstances, organisms display several antioxidant enzymes against ROS, and enhance protective processes, such as the accumulation of compatible solutes and increased activity of detoxifying enzymes [26]. Changes in the activity of these defense systems have been proposed as biomarkers for contaminant-mediated pro-oxidant challenge [27].
More detailed studies of the interactions between DSEs and their host plants reveal they have a beneficial role in plant growth and survival in various stressful environments [28], and DSE colonization improved the tolerance of host plants under various abiotic stresses such as metal contaminants, heat, salinity and drought [15,29, 30]. However, the current knowledge on the instinctive behavior of DSEs against metal toxicity is still limited. In the present study, a Zn-sensitive and a Zntolerant Exophiala spp. were targeted and their growth, Zn accumulation characteristics, and their modulation of antioxidant components and antioxidant enzyme activities were comparatively analyzed under different Zn2+ supplements.
2. Materials and Methods2.1. Exophiala Spp. Strains and Zn EC50In the current study, two DSE fungi were compared: the Zn-tolerant Exophiala pisciphila H93 (referred to as H93), and the Zn-sensitive B40-3 culture identified as Exophiala sp. by sequencing their internal transcribed spacer and large subunit rDNA, and phylogenetic analysis. H93 was isolated from the roots of Arundinella bengalensis that naturally grows in an ancient Pb–Zn slag heap at Huize, Yunnan Province, China and the Zn-sensitive B40-3 culture was isolated from the non-metal contaminated roots of Eupatorium adenophorum in the tropical rain forest of Xishuangbanna, Yunnan Province, China. Two DSE strains were deposited in Agricultural Culture Collection of China with accession number ACCC32496 (H93) and in China Forestry Culture Collection Center (CFCC89522) (B40-3) respectively.
The Zn tolerance of the two fungal strains was determined and expressed as the median effective concentration (EC50) of Zn2+, which results in inhibition of 50% clonal growth. Modified Melin-Norkrans (MMN) liquid media (CaCl2·2H2O, 0.05 g·L–1; maltose, 3.0 g·L–1; NaCl, 0.025 g·L–1; glucose, 10.0 g·L–1; K2HPO4, 0.5 g·L–1; VB1, 0.1 mg·L–1; MgSO4, 0.15 g·L–1; 1% FeCl3 solution, 1.2 ml·L–1; NaNO3, 3.0 g·L–1; and (NH4)2HPO4, 0.25 g·L–1; pH 5.5) were prepared and amended with the desired Zn2+ concentrations [31]. Then, 50 g·L–1 Zn2+ (ZnSO4·7H2O) stock solution was diluted to yield the desired concentrations (0, 200, 400, 600, 800, 1000, 1500, and 2000 mg·L–1 for H93, and 0, 25, 50 75, 100, and 200 mg·L–1 for B40-3). Each 250 mL Erlenmeyer flask containing 100 mL of the prepared media was inoculated with a fungal disk (Φ 0.6 cm) cut from a 14-day-old PDA culture. The Erlenmeyer flasks were incubated at 28˚C and 120 rpm agitation for 7 d and then filtered through a mediumspeed qualitative filter paper (Hangzhou Special Paper Co., Ltd., Hangzhou, China). Then, the mycelia were dried to a constant weight in an oven at 80˚C and weighed. The EC50 value was calculated by fitting a linear regression to the results from the inhibition of the biomass of the two fungal strains [32].
2.2. Biosorption and Accumulation of Zn by the Two Fungal StrainsTo determine the hyphal biosorption and accumulation of Zn, the two fungal strains were incubated under different Zn2+ supplements at 28˚C and agitated at 120 rpm for 7 d. Then, the mycelia in the 100 mL cultures were harvested, washed three times with 100 mL of distilled water, and as much liquid as possible was removed using a filter paper-covered Buchner funnel (medium-speed qualitative filter paper) using a vacuum pump (Yuhua Instrument Co., Ltd., Zhengzhou, China). Then 0.5 g mycelia were bathed for 30 min in 100 mM CaCl2 solution (100 mL) at 28˚C and 120 rpm agitation [16]. Then, the zinc concentrations in the CaCl2 eluting solution (for biosorption) and in the mycelia (for accumulation) were determined via a flame atomic absorption spectrometer (FAAS) using a Z2000 polarized Zeeman atomic absorption spectrophotometer (Hitachi, Japan). For the hyphal accumulation of Zn, 50 mg of the mycelia was digested using HNO3 + HClO4. Quantification was carried out with a calibration curve using a graded series of diluted Zn solutions (0, 0.1, 0.2, 0.4, 0.8, and 1.2 μg·mL–1) (GSW08620, National Research Center for Certified Reference Materials, China). The hollow cathode lamp was operated at 5 mA and the analytical wavelength was set to 213.9 nm for the detection of Zn [15].
2.3. Antioxidant SystemsUnder different Zn2+ supplements, the mycelia of the two fungal strains were harvested and washed as described above. The mycelia were then flash-frozen in liquid nitrogen and ground in a chilled mortar and pestle. Then, 0.5 g of the ground powder was collected into a new sterile centrifuge tube and suspended in 5 mL Tris buffer solution (50 mM, pH 7.8) and centrifuged at 8000 rpm for 30 min at 4˚C. The supernatant liquid was collected and used as cell-free extracts for the analysis of antioxidant activities [33]. T-SOD, POD, MDA, and GSH were determined according to the protocols of the Nanjing Jiancheng Bioengineering Institute (Nanjing, China) included in the kits.
2.4. Statistical AnalysisEach treatment of all above experiments was conducted in triplicate and the average values were used in the data analysis. The effects of Zn on mycelial biomass, mycelial heavy metal content, and hyphal enzyme activity are expressed as mean ± standard deviation (SD). The significant differences among the treatments were analyzed using a one-way ANOVA with statistical significance at P < 0.05 based on a least significant difference multiple range test.
3. Results and DiscussionThe growth of the two fungal strains was not restricted at lower Zn concentrations. However, the biomass of the two fungal strains decreased with increasing Zn2+ supplements (Figure 1). Our overall results were also in accordance with the original knowledge on Zinc. Zn is essential for the normal growth and development of almost all organisms including filamentous fungi, because it serves as a cofactor in many physiologic processes. However, it can be highly toxic at excessive levels [34]. Meanwhile, the two fungal strains showed significant differences in their Zn tolerance. H93 showed 50% growth inhibition (EC50) at 1010 mg·L–1 Zn, whereas the biomass of B40-3 was reduced by 50% at 26 mg·L–1 of Zn (EC50 for B40-3). Differences in zinc tolerance were found across different organisms and also across different strains of a given species, and Zn tolerance may be linked to their physiologic adaptation and the selection of their environment [35]. Cairney et al. [36] reported that the EC50 of Zn for ericoid mycorrhizal endophytes from Woollsia pungens is only 1.08 mg·L–1. However, the EC50 of Zn for Aspergillus niger isolated from polluted sites reach 1625 mg·L–1 [37]. In pioneer pine forests at 14 different locations along a Zn pollution gradient, Colpaert et al. [35] also reported that the severe Zn pollution surrounding Zn smelters clearly triggers the evolution of increased Zn tolerance in pioneer Suilloid fungi. With increasing distance from the Zn smelters, the frequency of Zn-tolerant genotypes decreases. The EC50 of the Zn-tolerant ectomycorrhizal basidiomycete Suillus luteus isolate (UH–Slu–Lm8) obtained from a heavy metal polluted site in Lommel is approximately nine fold higher than that of a Zn-sensitive isolate (UH–Slu–P13) obtained from a non-polluted site in Paal [38]. In the current study, H93 was isolated from an ancient lead and zinc slag heap [14], and exposure to heavy metals may trigger its physiological adaptation to Zn stress [35].
Mycelial biosorption and intracellular accumulation of Zn in H93 and B40-3 increased with the increasing extracellular Zn concentrations (Figure 2). The intracellular Zn accumulation was higher than that of the adsorptively bound Zn in both strains. Furthermore, the biosorption of Zn (presumed in the cell wall) and intracellular Zn of the Zn-tolerant strain (H93) were signficantly higher than those of the Zn-sensitive strain (B40-3), which suggested that both the cell wall and cytoplasm contribute to the Zn tolerance of Exophiala strains. In contrast to the three fold Zn biosorption by H93 compared with that by B40-3, the Zn accumulation of the two fungal strains was almost the same at 26 mg·L–1 Zn. The intracellular Zn accumulation of H93 was 5.24-fold higher
than that of B40-3 at their EC50 respectively; However, the biosorption by H93 was only 2.52-fold that by B40-3 (Figure 2). Consequently, although more Zn ions were uptaked and accumulated by the H93 mycelia than B40-3, less growth restriction occurred under the same metal stress. The prevailing theory argues that the binding of metals to the cell wall and compartmentalization in the vacuoles may be essential mechanisms for metal detoxification in various fungi [16,39,40]. Through energy-dispersive X-ray spectroscopy, González-Guerrero et al. [41] found that heavy metals accumulated mainly in the mycorrhizal fungal cell wall and in the vacuoles, whereas minor changes in metal concentrations were detected in the cytoplasm. Subsequent experiments showed that many of the proteins involved in metal transport and homeostasis, such as ZRT2, play essential roles in Zn nutriation and resistance in eukaryotic cells [42,43]. At 52 mg·L–1 Zn, the Zn accumulation and biosorption concentrations of B40-3 were almost the same, which suggested higher Zn concentrations might have disrupted the balance and severely damage the cell wall of B40-3 and further inhibited its growth.
In biochemical systems, Zn exerts its antioxidant properties, which appear to be mostly independent of Zn metalloenzyme activity [44]. However, excess Zn imposes severe effects on biomass production, biosorption, accumulation, and oxidative activities. Malondialdehyde (MDA) is a cytotoxic product of lipid peroxidation and an indicator of free radical production and consequent tissue damage [45]. Thus, the influence of Zn on the MDA production in the mycelia of the two fungal strains is determined and shown in Figure 3. The MDA content significantly increased when exposed to excess Zn after 7 d, and the effects of high Zn concentrations obviously enhanced the MDA content. The MDA content of H93 was 2.7-fold higher than that of B40-3 at their EC50 (Figures 3(a) and (b)). The current study suggested that free radical generation increased in H93 and B40-3 under Zn stress, as indicated by MDA. The MDA content of the two fungal strains increased with increasing Zn concentrations in the culture medium, which indicates concentration-dependent free radical generation similar to the effect of heavy metals on the cyanobacterium Spirulina platensis-S5 [26] and higher plants [46,47].
In general, the activated antioxidant defense system of cells is reportedly a compensatory mechanism for various organisms and the modulation of the antioxidant status is an important adaptive response to heavy metals [48]. Penninckx [49] found that GSH plays an important role as a cellular redox buffer when yeast cells are under environmental stress. At different Zn concentrations, the elevated extracellular Zn concentrations increased the GSH levels in both fungal strains, and showed a positive correlation between intracellular GSH content and extracellular Zn concentrations (Figures 3(c) and (d)). At their EC50, GSH in the H93 mycelia increased to 134% and 104% for B40-3 compared with their mycelia without Zn stress. The GSH content of H93 was 2.94-fold higher than that of B40-3 at their EC50 (Figures 3(c) and (d)).
In the present study, the correlation between external Zn concentration and antioxidant level was analyzed. The effects of excess Zn on the T-SOD and POD activity in the mycelia of both fungal strains are shown in Fig. 4. When the two fungal strains grew in the MMN liquid media without Zn, the T-SOD and POD activity in the mycelia were not significantly different and their contents were 16.33 U·mg–1 and 4.774 U·mg–1 protein for H93, and 18.443 U·mg–1 and 6.471 U·mg–1 protein for B40-3, respectively. However, the activity of the two antioxidant enzymes in the two fungal strains increased rapidly with the external Zn contaminant concentrations. The T-SOD and POD activity of H93 were 1.32-fold and 1.86-fold higher than that of B40-3 at their EC50, respectively (Figure 4). Presumably, T-SOD and POD play effective roles in protecting the two fungal strains from the ROS induced by high Zn2+ concentrations [50,51]. In
summary, the present study provides direct evidence of oxidative stress-mediated Zn toxicity in Exophiala strains. Differences in Zn accumulation and tolerance were observed within Exophiala strains, and physiologic adaptation and environmental selection may contribute to this difference. The cell wall and cytoplasm play effective roles in the Zn tolerance of Exophiala strains, and the antioxidant system in the cytoplasm, especially T-SOD and POD play important roles.