Main content area

Comparative investigation on a hexane-degrading strain with different cell surface hydrophobicities mediated by starch and chitosan

Chen, Dong-Zhi, Jiang, Ning-Xin, Ye, Jie-Xu, Cheng, Zhuo-Wei, Zhang, Shi-Han, Chen, Jian-Meng
Applied microbiology and biotechnology 2017 v.101 no.9 pp. 3829-3837
Fourier transform infrared spectroscopy, Pseudomonas mendocina, biodegradation, bioremediation, carbon dioxide, chitosan, electrostatic interactions, hexane, hydrophobicity, mass transfer, microorganisms, models, oxygen consumption, proteins, starch, water solubility
Bioremediation usually exhibits low removal efficiency toward hexane because of poor water solubility, which limits the mass transfer rate between the substrate and microorganism. This work aimed to enhance the hexane degradation rate by increasing cell surface hydrophobicity (CSH) of the degrader, Pseudomonas mendocina NX-1. The CSH of P. mendocina NX-1 was manipulated by treatment with starch and chitosan solution of varied concentrations, reaching a maximum hydrophobicity of 52%. The biodegradation of hexane conformed to the Haldane inhibition model, and the maximum degradation rate (ν ₘₐₓ) of the cells with 52% CSH was 0.72 mg (mg cell)⁻¹·h⁻¹ in comparison with 0.47 mg (mg cell)⁻¹·h⁻¹ for cells with 15% CSH. The production of CO₂ by high CSH cells was threefold higher than that by cells at 15% CSH within 30 h, and the cumulative rates of O₂ consumption were 0.16 and 0.05 mL/h, respectively. High CSH was related to low negative charge carried by the cell surface and probably reduced the repulsive electrostatic interactions between hexane and microorganisms. The FT-IR spectra of cell envelopes demonstrated that the methyl chain was inversely proportional to increasing CSH values, but proteins exhibited a positive effect to CSH enhancement. The ratio of extracellular proteins and polysaccharides increased from 0.87 to 3.78 when the cells were treated with starch and chitosan, indicating their possible roles in increased CSH.