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9 Biodegradation of Plastics by Microorganisms
9.3.6.5
Lignin Modifying Enzymes
Lignin modifying enzymes such as laccases (EC 1.10.3.2), manganese peroxidases
(MnP, EC 1.11.1.133), and lignin peroxidases (Lip, EC 1.11.1.14) are known to
degrade lignin, a complex cross-linked aromatic polymer of phenypropanoid units
[35]. These enzymes are responsible for the biodegradation of PE. In the presence
of iron, laccase, a thermo-stable enzyme isolated from R. ruber C208 can degrade
UV-irradiated PE films both in culture supernatants and in cell free extract. The key
mechanism involved in this process includes the increasing of carbonyl groups and
decreasing of molecular weight within the amorphous component of PE films. Sim-
ilarly, laccase isolated from Trametes versicolor can degrade high-molecular-weight
PE membrane, in the presence of 1-hydroxybenzotriazole, which oxidized
non-phenolic substrates by the enzyme. However, high-molecular-weight PE also
degraded by a combination of MnP from white-rot fungi (Phaerochaete chrysospo-
rium ME-446) and MnP isolated from IZU-154 [36]. This high-molecular-weight PE
also degraded by cell free supernatant from P. chrysosporium MTCC-787 containing
both extracellular LiP and MnP, respectively. The combination of Lip and MnP
enzymes permitted the degradation of 70% of the pre-oxidized high molecular
weight of PE with 15 days of reaction.
9.4
Current Trends and Future Prospects
There is an emerging trend in the use of environmental-friendly bio-based and
fossil-based biodegradable plastics. The proper use of biodegradable plastics
in the form of sustainable waste management approaches should be prac-
ticed worldwide. A recent research suggested that hydrolysis of PET and its
mono-2-hydroxyethyl-terepthalic acid to ethylene glycol and terephthalic acid is
occurred by two enzymes isolated from I. sakaiensis, 201-F6 strain [19]. Research
also illustrated that Pantoea spp. and Enterobacter spp. have the ability to degrade
LDPE [37]. Tan et al. [38] found some microbes convert the organic styrene (an
industrial waste material from plastic processing) into PHA. They also recognized
that P. putida NBUS12 is an efficient and effective styrene degrading bacterium.
Achromobacter xylosoxidans, a recently characterize bacteria, was found to affect
the structure of HDPE. Similarly, a thermophilic bacterium, named, Anoxybacillus
rupiensis Ir3 (JQ912241), was isolated from soil in Iraq, which confirmed a good
capacity and efficiency to utilize aromatic compounds as carbon sources followed by
degradation [39]. Extensive research is therefore required worldwide to improve the
process of degradation of bio-based and fossil-based plastics in order to recognize
their potential eco-friendly applications and waste management plans.
Innovative and eco-friendly biodegradable plastics should be used in the pack-
aging, agriculture, and heath industry which is the simplest strategy to resolve the
plastic-related problem throughout the world. Bio- and fossil-based biodegradable
polymers should be exploited more proficiently and effectively to degrade in
the cells, eco-friendly, or under optimized facilities. At present, however, only
non-biodegradable petroleum products are utilized for the processing of plastics,