Microbial Degradation Mechanism of Microplastics
Xueqin Wang
*
Chongqing College of Architecture and Technology, China
Keywords:
Microplastics, Microorganism, Microplastic Degradation Mechanism, Insect.
Abstract:
Microplastics refer to plastic particles with less than a diameter of 5mm and are a widely distributed, persistent
pollutant with environmental toxicity and biotoxicity. Microbial degradation of microplastics is an
environmentally friendly treatment technique without secondary pollution. On the basis of exploring the
degradation mechanism of microplastics by animals and microbial degradation mechanism of microplastics,
this paper analyzes the problems in the existence of microplastics degradation research, and puts forward the
research of microplastics degradation in the future, so as to provide a basis for the deep degradation research
of microplastics.
1 INTRODUCTION
Microbial degradation of microplastics mainly is the
use of microbial feeding, metabolism and other
processes to convert plastics and other organic waste
into water and carbon dioxide and other end products
into the geochemical cycle. Microbial degradation of
plastics is an environmentally friendly, no secondary
pollution, and relatively economical treatment
technology. At the same time, microbial genes are
heritable and adaptable, microbial genome is small,
and there are a large number of suitable molecular
operation means and tools can be used, which on the
one hand is conducive to the study of metabolic
mechanism, also to improve the efficiency of
microbial degradation or metabolic path, achieve the
actual production application demand. Therefore, the
biodegradation of microplastics has been widely
concerned by scholars. At present, on the
biodegradation of microplastics, one part studies the
rodent degradation effect of animals (mainly insects
and soil animals) on microplastics, and the other part
focuses on the study of microbial degradation of
microplastics, including some bacteria, fungi and
actinomycetes.
*
Wang Xueqin (1984-), female, associate professor,
master
2 MECHANISM OF
MICROPLASTICS
DEGRADATION BY ANIMAL
The degradation of plastic by insects or soil animals
mainly depends on the role of intestinal microbial
populations and enzymes with biodegradable plastic
in their intestines (Giacomucci, 2019). Different
insects have different ability to degrade plastics, and
different insects degrade different plastics. However,
the degradation efficiency of microplastics isolated
from the intestines of these animals in vitro is much
lower than that in the gut of (Yang, 2015), which may
mean that the degradation of plastics in insect (or soil
animal) intestines is the result of a combination of
biological-chemical reaction mechanisms.
The plastic degradation process by animals can be
divided into the following four steps:
1) Animals use mouthparts to chew plastic film
and grind in the foregut. This is mainly a physical
process.
2) Gut microorganisms in insect’s or soil animal’s
gut adhere to and erode plastic fragments. Bacillus,
Corynebacterium, microptococcus and streptococcus
erode the plastic and change its physical and chemical
properties in preparation for further degradation.
3) Plastic fragments are bioenzymatic or
enzymatically hydrolysed into oligomer fragments.
392
Wang, X.
Microbial Degradation Mechanism of Microplastics.
DOI: 10.5220/0012021500003633
In Proceedings of the 4th International Conference on Biotechnology and Biomedicine (ICBB 2022), pages 392-395
ISBN: 978-989-758-637-8
Copyright
c
2023 by SCITEPRESS Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
Key enzymes such as lipase and mitochondrial
carnitine acetyltransferase in insects or soil animals
cause-C-C-breakage of plastic and eventually
degrade plastic membranes.
4) After being degraded into oligomers by the
above three processes, plastics are further degraded
and metabolized, and they are eventually absorbed or
excreted by gut microbes or insect bodies.
Figure 1 summarizes the mechanism of plastic
degradation by microorganisms and key enzymes in
the gut of insects or soil animals.
Figure 1: Mechanism of plastic degradation in insect’s or soil animal’s gut.
As can be seen from Figure 1, the degradation
mechanism of plastic by insects or soil animals is
quite complicated. The degradation process of plastic
is the result of the chewing and crushing of plastic by
insects or soil animals, and the combined action of
enzymes, special secretions and microorganisms on
plastic particles in the insect gut.
3 MECHANISM OF
MICROBIOLOGICAL
DEGRADATION BY
MICROPLASTICS
In addition to animal gut microorganisms can
degrade plastic, microorganisms in the natural
environment or some special environment have the
ability to degrade plastic, and some bacteria can use
plastic as the sole carbon source.
In the process of plastic degradation,
microorganisms often secrete extracellular enzymes
to promote the degradation of plastic, which is the
most core active material in the process of plastic
degradation (Albertsson, 1998). For example,
trichomonas testosterone Comamonas testosteroni is
capable of producing different enzymes on the broken
link of ester bonds and the open ring of the benzene
ring, monooxygenase in microbial cells oxidizes PE
to hydroxyl group, which is further oxidized by
alcohol dehydrogenase, which can be further oxidized
to ester group, which further hydrolysis into
carboxylate low molecule products catalyzed by
esterase, and finally the product enters the central
metabolic cycle in the cell (Wasserbauer, 1990). PET
enzymes in the strain first hydrolyze PET into
ethylene glycol terebenzoate monomer (MHET) and
terephthalic acid (TPA) (Yoshida, 2016).
Subsequently, the enzyme speculated as lipoprotein
MHET enzyme hydrolyzes MHET into terephthalic
Step 1
Insects eat plastic
The degradation process of plastic in the insect gut
Microbial Degradation Mechanism of Microplastics
393
acid and ethylene glycol (EG). TPA is metabolically
oxidized by 1,2-dioxygenase, 1,2-dioxygenase, 1,2-
dihydroxy-3,5-cyclohexadiene-1,4-diethyl acetate
dehydrogenase after being transported to a specific
unit. The benzene ring on the end product, primary
catechin acid (PCA), is opened by PCA3,4-
dioxygenase.Figure 2 summarizes the metabolic
pathwayfor microbial degradation of PE and PET
.
Figure 2: Putative metabolic pathway of PE and PET by microbes.
To sum up, the microbial degradation of
microplastics is mainly divided into four steps.
1) Bio-deterioration. The microbial community
and abiotic factors work together to intercept the
polymer (plastic) into fragments.
2) Depolymerization. Microorganisms secrete
enzymes and free radicals. Transform the polymer
into an oligomer, dimer, or monomer. This process is
mainly a process in which hyperomers are cleaved or
oxidized to produce low molecular intermediates.
3) Assimilation. The depolymerized molecules
are recognized by the receptors on the microbial
surface to pass through the plasma membrane and
enter the microbial cell. This process is when low
Alcohol
Ketone
PE
Ester
Esterase
Carboxylic acid
Alcohol
TPA, EG
MHET
PCA
PET
Pca34
ICBB 2022 - International Conference on Biotechnology and Biomedicine
394
molecular products are taken up by microorganisms
and assimilated into their own cellular material.
4) Mineralization. The molecules are
depolymerized to small molecule compounds such as
CO2, N2, CH4 and H2O. The depolymerization
material is degraded by microorganisms into
methane, water and so on under aerobic conditions.
4 CONCLUSION
So far, although it has been confirmed that a variety
of plastics can be degraded by microorganisms, and
the microorganisms or biological enzymes that
degrade plastics have been found, but the current
research on the microbial degradation of plastics still
has the following problems.
1) At present, it is found that the degradation
efficiency of plastics by microorganisms is very slow.
So the means of optimizing microbial degradation
should be further explored, and the microbial
degradation pathway of high-efficiency plastics
should be deeply studied.
2) At present, there are few kinds of strains with
the ability to degrade plastics, so it is urgent to find
the microbial and enzyme systems that effectively
degrade plastics and enrich the resource pool of
degraded strains.
3) The microbial degradation mechanism of
microplastics is not clear, and is only a preliminary
understanding of the degradation process. The
research on the enzymatic, chemical and energy
metabolism of the microplastic degradation process
should be strengthened, the key enzymes and their
mechanisms should be determined, and the gene
modification research of the key enzymes for
degradation should improve their activity and yield.
4) Some microorganisms in the gut of animals
have the ability to degrade microplastics in animals,
but not in the in vitro environment. In future studies,
the degradation level can be improved by the
modification of known degrading bacteria or the
optimization of experimental conditions.
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