Division of Industrial & Environmental Biotechnology, National Institute of Genetic Engineering and Biotechnology (NIGEB), P. O. Box 14155-6343, Tehran, Iran.
Department of Isotope Biogeochemistry, Helmholtz Centre for Environmental Research-UFZ, Permoserstraße 15, 04318 Leipzig, Germany.
Ecotoxicol Environ Saf. 2018 Nov 30;164:455-466. doi: 10.1016/j.ecoenv.2018.08.051. Epub 2018 Aug 22.
An efficient phenol-degrading bacterial strain, belonging to Acinetobacter genus, was isolated and selected to study the impact of different environmentally relevant phenol concentrations on the degradation process. The bacterial isolate, labeled as Acinetobacter sp. SA01 was able to degrade the maximum phenol concentration of 1 g/l during 60 h at optimum condition of pH 7, 30 °C and 180 rpm. Aeration and initial cell density, the two important factors, were carefully examined in the optimal growth conditions. The results showed that these two variables related proportionally with phenol degradation rate. Further investigations showed no effect of inoculum size on the enhancement of degradation of phenol at over 1 g/l. Flow cytometry (FCM) study was performed to find out the relationship between phenol-induced damages and phenol degradation process. Single staining using propidium iodide (PI) showed increased cell membrane permeability with an increase of phenol concentration, while single staining with carboxyfluorescein diacetate (cFDA) demonstrated a considerable reduction in esterase activity of the cells treated with phenol at more than 1 g/l. A detailed investigation of cellular viability using concurrent double staining of cFDA/PI revealed that the cell death increases in cells exposed to phenol at more than 1 g/l. The rate of cell death was low but noticeable in the presence of phenol concentration of 2 g/l, over time. Phenol at concentrations of 3 and 4 g/l caused strong toxicity in living cells of Acinetobacter sp. SA01. The plate count method and microscopy analysis of the cells treated with phenol at 1.5 and 2 g/l confirmed an apparent reduction in cell number over time. It was assumed that the phenol concentrations higher than 1 g/l have destructive effects on membrane integrity of Acinetobacter sp. SA01. Our results also revealed that the toxicity did not reduce by increasing initial cell density. Scanning electron microscopy (SEM) examination of bacterial cells revealed the surface morphological changes following exposure to phenol. The bacterial cells, with wizened appearance and wrinkled surface, were observed by exposing to phenol (1 g/l) at lag phase. A morphological change occurred in the mid-logarithmic phase as the bacterial cells demonstrated coccobacilli form as well as elongated filamentous shape. The wrinkled cell surface were totally disappeared in mid-stationary phase, suggesting that the complete degradation of phenol relieve the stress and direct bacterial cells toward possessing smoother cell membrane.
一株高效苯酚降解菌,属于不动杆菌属,被分离并选择来研究不同环境相关苯酚浓度对降解过程的影响。分离得到的细菌菌株被标记为不动杆菌 sp. SA01,在最佳条件下(pH7、30°C 和 180rpm),可在 60 小时内降解最大 1g/L 的苯酚浓度。通气和初始细胞密度这两个重要因素在最佳生长条件下进行了仔细研究。结果表明,这两个变量与苯酚降解率呈比例关系。进一步的研究表明,在超过 1g/L 的苯酚浓度下,接种量的增加对苯酚降解的增强没有影响。进行了流式细胞术 (FCM) 研究,以找出苯酚诱导的损伤与苯酚降解过程之间的关系。使用碘化丙啶 (PI) 进行单一染色显示,随着苯酚浓度的增加,细胞膜通透性增加,而用羧基荧光素二乙酸酯 (cFDA) 进行单一染色则表明,在超过 1g/L 的苯酚处理下,细胞的酯酶活性显著降低。使用 cFDA/PI 同时进行双重染色对细胞活力进行详细研究表明,在超过 1g/L 的苯酚存在下,暴露于苯酚的细胞的细胞死亡增加。在有 2g/L 苯酚存在的情况下,细胞死亡率较低,但随着时间的推移,细胞死亡率会增加。3g/L 和 4g/L 的苯酚浓度对不动杆菌 sp. SA01 的活细胞造成了强烈的毒性。用苯酚处理 1.5g/L 和 2g/L 的细胞的平板计数法和显微镜分析证实,随着时间的推移,细胞数量明显减少。可以假设,超过 1g/L 的苯酚浓度对不动杆菌 sp. SA01 的膜完整性具有破坏性影响。我们的结果还表明,增加初始细胞密度并不能降低毒性。用苯酚处理后,用扫描电子显微镜 (SEM) 检查细菌细胞,发现了表面形态的变化。在迟缓期,用苯酚(1g/L)处理时,细菌细胞呈现出干瘪和皱缩的外观。在对数中期,细菌细胞表现出类似球杆菌的形态以及拉长的丝状形态,发生了形态变化。在中期静止期,皱缩的细胞表面完全消失,这表明苯酚的完全降解缓解了压力,并使细菌细胞向具有更光滑细胞膜的方向发展。
