Harnessing fungi and bacteria to speed up the biodegradation of plastic mulch films

Davi R. Munhoz; Ke Meng; Luis F. Merloti; Violette Geissen; Jianhua Zhang; Paula Harkes

doi:10.1016/j.scitotenv.2026.181778

Harnessing fungi and bacteria to speed up the biodegradation of plastic mulch films

Davi R. Munhoz^*
, Ke Meng
, Luis F. Merloti
, Violette Geissen
, Jianhua Zhang
, Paula Harkes

^*Corresponding author for this work

NIOO - Terrestrial Ecology (TE)

Research output: Contribution to journal/periodical › Article › Scientific › peer-review

Abstract

Plastics and microplastics are pervasive in agricultural systems, underscoring the need for effective mitigation strategies. Here, we explored microbial treatments to accelerate the degradation of plastic mulch films composed of commercial (LDPE-m) and additive-free (LDPE-p) low-density polyethylene and a blend containing polybutylene adipate-co-terephthalate and polylactic acid (PBAT-PLA). We tested four microbial treatments: a compost-derived microbial community (m1), a multi-strain Aspergillus consortium with Peribacillus simplex (B. simplex) (m2), an Aspergillus-only fungal consortium (m3), and an Aspergillus fumigatus–Pseudomonas aeruginosa co-culture (m4). These were incubated under carbon-free (CF), low-carbon (LC), autoclaved compost (AC), and raw compost (C) conditions (at 30 °C for 180 days), with and without abiotic pre-treatments (UV-aging and mineral oil amendment (MO)) to accelerate microorganisms association with plastics. Our results show that the Aspergillus-only consortium (m3) accelerated LDPE-m degradation (3.71 ± 0.86 WL, Mw = −17.2 kDa and O-H and C-O formation) while the fungal–bacterial co-culture (m4) quickened LDPE-m weight loss (2.79 ± 0.95%) and C-O formation in CF media. Multi-strain Aspergillus consortium with B. simplex (m2) colonized the UV-aged LDPE-m plastisphere in AC, and the m1-dwelling Brucella combined with Aspergillus sp. optimized UV-aged LDPE-m degradation patterns. The co-occurrence of compost-dwellers Gordonia, Thermomyces, and Mycobacterium with inoculated Aspergillus sp. enhanced LDPE-p weight loss (4.91 ± 2.28%) and surface changes (C-O formation) in compost under MO. Most Aspergillus treatments dominated the plastisphere in autoclaved compost and were eclipsed by Thermomyces in compost. Slower-than-expected degradation occurred for PBAT-PLA mulch films. This study sheds light on possible microbial treatments for accelerating the degradation of plastic mulches.

Original language	English
Article number	181778
Journal	Science of the Total Environment
Volume	1030
DOIs	https://doi.org/10.1016/j.scitotenv.2026.181778
Publication status	Published - 15 May 2026

Keywords

Aspergillus
Bacillus
Compost
Microplastics
Niche
Plastisphere
Thermomyces

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10.1016/j.scitotenv.2026.181778Licence: CC BY

Cite this

@article{588051ab07ab4ff1833f6029368c24ad,

title = "Harnessing fungi and bacteria to speed up the biodegradation of plastic mulch films",

abstract = "Plastics and microplastics are pervasive in agricultural systems, underscoring the need for effective mitigation strategies. Here, we explored microbial treatments to accelerate the degradation of plastic mulch films composed of commercial (LDPE-m) and additive-free (LDPE-p) low-density polyethylene and a blend containing polybutylene adipate-co-terephthalate and polylactic acid (PBAT-PLA). We tested four microbial treatments: a compost-derived microbial community (m1), a multi-strain Aspergillus consortium with Peribacillus simplex (B. simplex) (m2), an Aspergillus-only fungal consortium (m3), and an Aspergillus fumigatus–Pseudomonas aeruginosa co-culture (m4). These were incubated under carbon-free (CF), low-carbon (LC), autoclaved compost (AC), and raw compost (C) conditions (at 30 °C for 180 days), with and without abiotic pre-treatments (UV-aging and mineral oil amendment (MO)) to accelerate microorganisms association with plastics. Our results show that the Aspergillus-only consortium (m3) accelerated LDPE-m degradation (3.71 ± 0.86 WL, Mw = −17.2 kDa and O-H and C-O formation) while the fungal–bacterial co-culture (m4) quickened LDPE-m weight loss (2.79 ± 0.95\%) and C-O formation in CF media. Multi-strain Aspergillus consortium with B. simplex (m2) colonized the UV-aged LDPE-m plastisphere in AC, and the m1-dwelling Brucella combined with Aspergillus sp. optimized UV-aged LDPE-m degradation patterns. The co-occurrence of compost-dwellers Gordonia, Thermomyces, and Mycobacterium with inoculated Aspergillus sp. enhanced LDPE-p weight loss (4.91 ± 2.28\%) and surface changes (C-O formation) in compost under MO. Most Aspergillus treatments dominated the plastisphere in autoclaved compost and were eclipsed by Thermomyces in compost. Slower-than-expected degradation occurred for PBAT-PLA mulch films. This study sheds light on possible microbial treatments for accelerating the degradation of plastic mulches.",

keywords = "Aspergillus, Bacillus, Compost, Microplastics, Niche, Plastisphere, Thermomyces",

author = "Munhoz, \{Davi R.\} and Ke Meng and Merloti, \{Luis F.\} and Violette Geissen and Jianhua Zhang and Paula Harkes",

note = "Data archiving: no NIOO data",

year = "2026",

month = may,

day = "15",

doi = "10.1016/j.scitotenv.2026.181778",

language = "English",

volume = "1030",

journal = "Science of the Total Environment",

issn = "0048-9697",

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TY - JOUR

T1 - Harnessing fungi and bacteria to speed up the biodegradation of plastic mulch films

AU - Munhoz, Davi R.

AU - Meng, Ke

AU - Merloti, Luis F.

AU - Geissen, Violette

AU - Zhang, Jianhua

AU - Harkes, Paula

N1 - Data archiving: no NIOO data

PY - 2026/5/15

Y1 - 2026/5/15

N2 - Plastics and microplastics are pervasive in agricultural systems, underscoring the need for effective mitigation strategies. Here, we explored microbial treatments to accelerate the degradation of plastic mulch films composed of commercial (LDPE-m) and additive-free (LDPE-p) low-density polyethylene and a blend containing polybutylene adipate-co-terephthalate and polylactic acid (PBAT-PLA). We tested four microbial treatments: a compost-derived microbial community (m1), a multi-strain Aspergillus consortium with Peribacillus simplex (B. simplex) (m2), an Aspergillus-only fungal consortium (m3), and an Aspergillus fumigatus–Pseudomonas aeruginosa co-culture (m4). These were incubated under carbon-free (CF), low-carbon (LC), autoclaved compost (AC), and raw compost (C) conditions (at 30 °C for 180 days), with and without abiotic pre-treatments (UV-aging and mineral oil amendment (MO)) to accelerate microorganisms association with plastics. Our results show that the Aspergillus-only consortium (m3) accelerated LDPE-m degradation (3.71 ± 0.86 WL, Mw = −17.2 kDa and O-H and C-O formation) while the fungal–bacterial co-culture (m4) quickened LDPE-m weight loss (2.79 ± 0.95%) and C-O formation in CF media. Multi-strain Aspergillus consortium with B. simplex (m2) colonized the UV-aged LDPE-m plastisphere in AC, and the m1-dwelling Brucella combined with Aspergillus sp. optimized UV-aged LDPE-m degradation patterns. The co-occurrence of compost-dwellers Gordonia, Thermomyces, and Mycobacterium with inoculated Aspergillus sp. enhanced LDPE-p weight loss (4.91 ± 2.28%) and surface changes (C-O formation) in compost under MO. Most Aspergillus treatments dominated the plastisphere in autoclaved compost and were eclipsed by Thermomyces in compost. Slower-than-expected degradation occurred for PBAT-PLA mulch films. This study sheds light on possible microbial treatments for accelerating the degradation of plastic mulches.

AB - Plastics and microplastics are pervasive in agricultural systems, underscoring the need for effective mitigation strategies. Here, we explored microbial treatments to accelerate the degradation of plastic mulch films composed of commercial (LDPE-m) and additive-free (LDPE-p) low-density polyethylene and a blend containing polybutylene adipate-co-terephthalate and polylactic acid (PBAT-PLA). We tested four microbial treatments: a compost-derived microbial community (m1), a multi-strain Aspergillus consortium with Peribacillus simplex (B. simplex) (m2), an Aspergillus-only fungal consortium (m3), and an Aspergillus fumigatus–Pseudomonas aeruginosa co-culture (m4). These were incubated under carbon-free (CF), low-carbon (LC), autoclaved compost (AC), and raw compost (C) conditions (at 30 °C for 180 days), with and without abiotic pre-treatments (UV-aging and mineral oil amendment (MO)) to accelerate microorganisms association with plastics. Our results show that the Aspergillus-only consortium (m3) accelerated LDPE-m degradation (3.71 ± 0.86 WL, Mw = −17.2 kDa and O-H and C-O formation) while the fungal–bacterial co-culture (m4) quickened LDPE-m weight loss (2.79 ± 0.95%) and C-O formation in CF media. Multi-strain Aspergillus consortium with B. simplex (m2) colonized the UV-aged LDPE-m plastisphere in AC, and the m1-dwelling Brucella combined with Aspergillus sp. optimized UV-aged LDPE-m degradation patterns. The co-occurrence of compost-dwellers Gordonia, Thermomyces, and Mycobacterium with inoculated Aspergillus sp. enhanced LDPE-p weight loss (4.91 ± 2.28%) and surface changes (C-O formation) in compost under MO. Most Aspergillus treatments dominated the plastisphere in autoclaved compost and were eclipsed by Thermomyces in compost. Slower-than-expected degradation occurred for PBAT-PLA mulch films. This study sheds light on possible microbial treatments for accelerating the degradation of plastic mulches.

KW - Aspergillus

KW - Bacillus

KW - Compost

KW - Microplastics

KW - Niche

KW - Plastisphere

KW - Thermomyces

U2 - 10.1016/j.scitotenv.2026.181778

DO - 10.1016/j.scitotenv.2026.181778

M3 - Article

C2 - 41962302

AN - SCOPUS:105035121387

SN - 0048-9697

VL - 1030

JO - Science of the Total Environment

JF - Science of the Total Environment

M1 - 181778

ER -

Harnessing fungi and bacteria to speed up the biodegradation of plastic mulch films

Abstract

Keywords

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