Lignocellulose-mediated selection of potential halophilic PET-degrading enzymes from mangrove soil

Titelangaben

Peña-Valencia, María Fernanda ; Robaina-Estévez, Semidán ; Custer, Gordon F. ; Turak, Onur ; Sierra, Felipe ; Mendes, Lucas William ; Rubiano-Labrador, Carolina ; Gutiérrez, Jay ; Vaksmaa, Annika ; Dini-Andreote, Francisco ; Rosado, Alexandre Soares ; Reyes, Alejandro ; Jiménez, Diego Javier:
Lignocellulose-mediated selection of potential halophilic PET-degrading enzymes from mangrove soil.
In: Nature Communications. (7 April 2026) .
ISSN 2041-1723
DOI: https://doi.org/10.1038/s41467-026-71548-z

Volltext

Link zum Volltext (externe URL):

Angaben zu Projekten

Abstract

Mangroves are ecosystems located at land–sea transition zones, where they are continuously exposed to plant biomass and plastic pollution. Their soils harbor extensive microbial diversity with potential for discovering polymer-degrading enzymes. Here, we perform a microcosm experiment to examine how mangrove soil microbial communities respond to inputs of lignocellulose or polyethylene terephthalate (PET) in the presence and absence of seawater, and to explore the selection of putative PET-active enzymes (PETases) using gene- and genome-resolved metagenomics. Incubation conditions lead to a gradual increase in salinity, resulting in the enrichment of halophilic taxa, including spore-forming bacteria and archaeal species, particularly in seawater-depleted treatments. Lignocellulose input is the primary driver of soil microbial community restructuring, followed by seawater presence. In dry, lignocellulose-amended microcosms (L treatment), microbial diversity is significantly reduced, while lignocellulolytic taxa within the phyla Bacillota and Actinomycetota are enriched. Twelve potential PETases are identified in the L treatment, sharing >70% sequence similarity with known PETases, and three are predicted to be thermostable. Two putative PETases from Microbulbifer species display distinct sequence and structural features, thereby expanding the currently limited PETase sequence landscape. This study demonstrates that perturbing environmental microbiomes with plant-derived polymers represents a promising strategy for capturing novel PETases.