4.4 Bioremediation Methods
53
because complete mineralization is achieved due to the synergy of different organ-
isms. According to reports, the reduction of azo bonds can be achieved under the
reducing conditions of an anaerobic bioreactor. As a result, a colorless aromatic
amine can be formed, which is further mineralized under aerobic conditions. There-
fore, it is usually recommended to perform anaerobic decolorization first and then
to perform aerobic posttreatment to treat dye wastewater. This combined approach
is cost-competitive and applicable to various dyes [4].
4.4.3
Decolorization and Degradation of Dyes by Fungi
Fungi can quickly adapt their metabolism to various carbon and nitrogen sources
by producing a large number of intracellular and extracellular enzymes that can
degrade a variety of complex organic pollutants. This ability of fungus to degrade
various organic compounds is caused by the relative non-specificity of their
lignin-decomposing enzymes, such as manganese peroxidase, lignin peroxidase,
and laccase [5]. Most research on the biodegradation of azo dyes has focused
on fungal cultures derived from white-rot fungi that have been used to develop
biological processes for the mineralization of azo dyes. P. chrysosporium is the
most widely studied white-rot fungus, but others have also received considerable
attention, such as Aspergillus ochraceus, Bjerkandera adusta, Trametes versicolor,
species of Phlebia, and Pleurotus, Peyronellaea prosopidis, and many other isolates.
However, the application of white-rot fungi to remove dyes from textile wastewater
has some inherent disadvantages, such as long growth cycles and the need for
nitrogen-limiting conditions.
4.4.4
Decolorization and Degradation of Dyes by Yeast
There is very little work to explore the decolorization ability of yeast, and it has been
used mainly for the study of biosorption. Some yeast species, such as Debaryomyces
polymorphus, Candida zeylanoides, and Candida tropicalis, have been used to per-
form putative enzymatic biodegradation and subsequent decolorization of different
azo dyes [6]. Recently, it has been reported that Saccharomyces cerevisiae MTCC-463
plays a role in the decolorization of malachite green and methyl red [7]. In addition,
S. cerevisiae cells also showed the bioaccumulation of reactive textile dyes (Remazol
Black B, Remazol Blue, and Remazol Red RB) during growth in molasses [8]. Recently,
the decolorization of Reactive Black 5 has been studied in detail using a salt-tolerant
yeast strain Sterigmatomyces halophilus SSA-1575, and the enzymatic mechanism
and toxicity of the degradation products have also been reported [9].
4.4.5
Decolorization and Degradation of Dyes by Algae
Photosynthetic organisms are ubiquitous, distributed in many habitats around
the world, and are receiving more and more attention in the field of wastewater
decolorization. Literature surveys indicate that algae can degrade azo dyes through
an induced form of azo reductase. Several species of Chlorella and Oscillatoria are
able to degrade azo dyes into their aromatic amines and can further metabolize