Department of Biotechnology, Birla College of Arts, Science and Commerce, Thane Dist, Kalyan, MS, India.
Bioxia, H-7 Rajlakshmi complex khaler Bhiwandi Thane, Bhiwandi, India.
J Fluoresc. 2021 Sep;31(5):1445-1459. doi: 10.1007/s10895-021-02769-2. Epub 2021 Jul 15.
Metal sulfide nanoparticles are semi-conductors that possess many applications in optics, optoelectronics and magnetic devices. There are physical and chemical methods for their synthesis but such methods involve toxic precursors as well as many obnoxious by-products. Hence, biological synthesis of metal sulfide nanoparticles are efficient enough to transform toxic metals to non-toxic ones. Pseudomonas aeruginosa, isolated from textile effluent and tolerant of high levels of heavy metals, was used for the green synthesis of metal sulfide (HgS, AsS, CdS and PbS) nanoparticles. The optical, structural and morphological nature of metal sulfide nanoparticles was also determined. FTIR (Fourier Transform Infra-red) analysis showed spectral changes when P. aeruginosa was grown in medium containing heavy metals viz. Hg, As, Pb and Cd indicating that there are functional groups viz. carboxyl, hydroxyl, phosphate, amino and amide, that exists on the surface of the bacteria, thus facilitating binding of metals on its surface. The bacterial samples which were treated with different metals at different concentrations, were subjected to whole cell protein analysis using SDS-PAGE (Sodium dodecyl Sulphate- Polyacrylamide gel electrophoresis) and protein profiling. The total protein estimation revealed that there was an increase in the protein concentration in the presence of heavy metals and a significant change in the banding pattern was observed which showed induction of a set of proteins under heavy metal stress especially mercury.
金属硫化物纳米粒子是半导体,在光学、光电学和磁性器件中具有许多应用。有物理和化学方法可以合成它们,但这些方法涉及有毒前体以及许多讨厌的副产物。因此,金属硫化物纳米粒子的生物合成效率足够高,可以将有毒金属转化为无毒金属。从纺织废水中分离出来并能耐受高浓度重金属的铜绿假单胞菌被用于绿色合成金属硫化物(HgS、AsS、CdS 和 PbS)纳米粒子。还确定了金属硫化物纳米粒子的光学、结构和形态性质。傅里叶变换红外(FTIR)分析表明,当铜绿假单胞菌在含有重金属(如 Hg、As、Pb 和 Cd)的培养基中生长时,光谱发生变化,这表明细菌表面存在功能基团,如羧基、羟基、磷酸根、氨基和酰胺基,从而促进了金属在其表面的结合。用不同浓度的不同金属处理细菌样品后,用 SDS-PAGE(十二烷基硫酸钠-聚丙烯酰胺凝胶电泳)和蛋白质谱进行全细胞蛋白质分析。总蛋白估计表明,在重金属存在的情况下,蛋白质浓度增加,并且观察到条带模式的显著变化,这表明在重金属胁迫下诱导了一组蛋白质,特别是汞。
