Microbe-Assisted Bioremediation of Pesticides from Contaminated Habitats 115
Figure 7.2. Mechanisms of pesticide degradation in bacterial system.
metabolite is conjugated to a sugar or amino acid, that increases its water solubility and reduces its
toxicity. During the third phase, phase two metabolites are converted into secondary conjugates,
which are also non-toxic (Ramakrishnan et al. 2011). The overall metabolism of pesticides by
enzymes proves to be favorable, as enzymes are more resistant to environmental conditions, which
makes it easier for them to remove pesticides more efficiently from affected areas (Huang et al.
2008). Therefore, it is imperative to identify species of bacteria that can thrive in extreme conditions
and completely degrade pesticides. A combination of mechanistic approaches and microbial genetic
advancement can enhance sustainable pesticide bioremediation by identifying the most effective
bacterial strains or bacterial consortia.
7.4.2 Phyco-assisted Degradation
The persistence of pesticides creates a grave threat to the environment, and their removal is crucial
in maintaining stability in the ecosystem (Bodin 2014). For many years, biological approaches have
been used in the removal of inorganic pollutants such as pesticides. There is a growing interest in
cyanobacteria and micro- and macroalgae as potent organisms for removing pesticides. It has been
shown that these organisms easily adapt to environmental changes and can grow efficiently under
various stress conditions (Mata et al. 2010). A wide range of photosynthetic algae exist, ranging
from single cells to multicellular organisms (Singh et al. 2020). They can grow in the presence and
absence of light and utilize organic carbon as an energy source (Subashchandrabose et al. 2013). As
part of a sustainable future, these photosynthetic microorganisms can be used for the remediation
of pesticides at contaminated sites. Research on phycoremediation technology, i.e., the utilization
of microalgae/cyanobacteria and their consortia as bioremediating agents, has proved to have
promising potential. Several authors have reported that common algal strains can remove pesticides
from contaminated environments, mainly by biosorption, bioaccumulation and biodegradation
(Table 7.3) (Verasoundarapandian et al. 2022).
Pesticide biosorption occurs in both living and dead photosynthetic organisms, as this
mechanism is not dependent on energy for the removal of pesticides in contaminated environments.