褐腐菌在不同条件下对偶氮染料的生物去除作用。

Role of brown-rot fungi in the bioremoval of azo dyes under different conditions.

机构信息

Department of Microbiology, Quaid-i-Azam University , Islamabad , Pakistan.

出版信息

Braz J Microbiol. 2010 Oct;41(4):907-15. doi: 10.1590/S1517-83822010000400009. Epub 2010 Dec 1.

DOI:10.1590/S1517-83822010000400009

PMID:24031570

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3769768/

Abstract

The present study is vital to the understanding of bioremediation of structurally different azo dyes by some unusual Brown-rot fungi. Bioremoval of each dye (20 mg l(-1)) was tested in two different culture media under static and shaking conditions by taking inocula from different fungi. Fungal strains showed varying dyes removal abilities, though considerable high in case of Acid Red (AR) 151(di-azo) as compared to Orange (Or) II (mono-azo). With an exception of Aspergillus tereus SA3, all the fungal isolates showed higher removal of dyes in SDB. Under static condition, the maximum decolorizing fungal strains were; Aspergillus flavus SA2 (67%) and Alternaria spp. SA4 (57%) in AR 151, while Penicillium spp. (34 and 33 %) in Orange II, in SDB and STE, respectively. Bioremoval of dyes was considerably increased when experiments were shifted from static to shaking mode. It was specifically increased (%) in; AR 151 (255) with Penicillium spp., Or II with A. flavus SA2 (112) and Alternaria spp. (111). The primary mechanism of dyes removal proved to be fungal biosorption. However, reduction of dyes (onto fungal) with formation of their products (α. naphthol, sulphalinic acid and aniline) furthermore revealed that dyes (specifically azo) were actually biodegraded.

摘要

本研究对于理解某些不寻常的棕腐真菌对结构不同偶氮染料的生物修复至关重要。通过从不同真菌中接种，在静态和振荡条件下，在两种不同的培养基中测试了每种染料（20mg l(-1)) 的生物去除。真菌菌株表现出不同的染料去除能力，尽管与橙色 II（单偶氮）相比，酸性红 151（二偶氮）相当高。除了曲霉属 SA3 外，所有真菌分离物在 SDB 中均表现出较高的染料去除率。在静态条件下，最大脱色真菌菌株是：黄曲霉 SA2（67%）和交替单胞菌 SA4（57%）在 AR 151 中，而青霉菌属（34%和 33%）在 SDB 和 STE 中的橙色 II。当实验从静态转移到振荡模式时，染料的生物去除率显著增加。具体增加了（%）：在 Penicillium spp. 的 AR 151 中增加了 255%，在 A. flavus SA2 的橙色 II 中增加了 112%，在交替单胞菌 SA4 中增加了 111%。染料去除的主要机制被证明是真菌的生物吸附。然而，染料（在真菌上）的还原伴随着其产物（α-萘酚、亚硫酸盐和苯胺）的形成，进一步表明染料（特别是偶氮）实际上被生物降解了。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8aa0/3769768/2fd665c123e1/bjm-41-907-g001.jpg

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褐腐菌在不同条件下对偶氮染料的生物去除作用。

Role of brown-rot fungi in the bioremoval of azo dyes under different conditions.

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