Bioremediation: A Sustainable Approach for Environmental Cleanup 9
Table 1.3. Pesticides degrading microorganisms.
Pesticides
Microorganism
References
Endosulfan
Micrococcus sp. strain, 2385
Pathak et al. 2016
DDT
Ochrobacterum sp.
Pan et al. 2017
Nitrophenol
Rhodoccus sp.
Sengupta et al. 2019
Cypermethrin chlordecone
Bacillus subtilis
Gangola et al. 2018
Citrobacter
Chaussonnerie et al. 2016
(Lindane) hexachloro-cyclohexane
Microbacterium
Zhang et al. 2020
Chloropyrifos, diazinon
Streptomyces sp.
Briceño et al. 2018
S- triazine (atrazine)
Arthrobacter sp. Strain Ak-YNIO
Sagarkar et al. 2016
Hexachloro-cyclohexane
Paenibacillus dendritiformis SJPS-4
Jaiswal et al. 2022
Glyphosate, 2-4D, Atrazine
Bradyrhizobium sp. BR 3901
Barroso et al. 2020
Endosulfan
Aspergillus trichoderma spp.
Gangola et al. 2015
Atrazine
Fusarium sp.
Esparza-Naranjo et al. 2021
Degrading enzymes are relatively more resistant to anomalous environmental circumstances
than microbial cells capable of producing such enzymes, and their degradable efficiency is
substantially higher than that of microorganisms, especially at low pesticide doses. As a result, using
degrading enzymes to detoxify the environment that has been contaminated by pesticides would be
a more effective method.
1.5.4 Bioremediation of Textile Dyes
Various industrial effluents, including those from textile, printing, pharmaceutical and other
industries, cause wastewater contamination (Uday et al. 2016). Dyes industries were established
during the same period of rapid industrialization and urbanization as other sectors. Many different
kinds of dyes are present in textile effluents. Based on their chemical makeup, dyes are divided
into several categories, such as Anthraquinone bases, metal complex dyes, di-azo and basic dyes.
These dyes might be cationic, anionic or neutral (Vikrant et al. 2018). According to Daneshvar et al.
(2007), artificial dyes, such as azo, xanthenes and anthraquinone dyes, are extremely toxic to living
things. When the dye forms compounds with other contaminants and deteriorates materials in the
environment, its toxicity increases. Additionally, these dyes can contribute to hereditary illnesses
that are incurable (Lellis et al. 2019).
Dyes can come from natural or synthetic sources or they can be generated via an inorganic
technique, in the wastewater produced by textile manufacturers (Varjani et al. 2021). Synthetic dyes
are inexpensive ingredients that come in large quantities, as well as being commonly used (Rossi
et al. 2017). Common dyes are anthraquinone dyes, that have polycondensed ring structures and
hydroxyl or amino functionalities. Different kinds of microorganisms used in the biodegradation of
textile dyes are given in Table 1.4.
Various enzymes are used in the decolorization of textile dyes, including formate dehydrogenase,
oxidases based on glyoxal and aryl-alcohol compounds and peroxidase (Chen et al. 2016, Sarkar
et al. 2017). Laccases are valuable enzymes in the decolorizing process because aromatic compounds
with azo and anthraquinone linkages are some of their substrates. Laccase is a multicooper oxidase
enzyme that may be found in a variety of microorganisms (e.g., microalgae, fungi and bacteria)
(Motamedi et al. 2021). A biodegradation pathway for Congo Red Dye utilizing azoreductase and
laccase was proposed by Lade et al. (2015). By breaking azo bonds in the presence of azoreductase,
the biodegradation of Congo Red Dye produces biphenyl-4, 4′-diamine and an unexplained
intermediate. As a result of this microbial degradation phase, the dye is decolored and aromatic
amines are formed as an end product. Furthermore, the presence of laccase causes the production