Co-cropping with three phytoremediation crops influences rhizosphere microbiome community in contaminated soil
N.J.B.Brereton, et al., 2020
Phytoremediation of contaminated soils using monoculture and co-cropping.
Festuca arundinacea, Salix miyabeana and Medicago sativa were compared.
Differential abundance analysis of highly resolved rhizosphere microbiomes.
Co-cropped pairs had more rhizosphere-associated bacteria than their monocultures.
Phytoremediation adaptability could be improved by increased ecosystem services.
Human industrial activities have left millions of hectares of land
polluted with trace element metals and persistent organic pollutants
(POPs) around the world. Although contaminated sites are environmentally
damaging, high economic costs often discourage soil remediation
efforts. Phytoremediation is a potential green technology solution but
can be challenging due to the diversity of anthropogenic contaminants.
Co-cropping could provide improved tolerance to diverse soil challenges
by taking advantage of distinct crop capabilities. Co-cropping of three
species with potentially complementary functions, Festuca arundinacea, Salix miyabeana and Medicago sativa,
perform well on diversely contaminated soils. Here, rhizosphere
microbiomes of each crop in monoculture and in all co-cropping
combinations were compared using 16S rRNA gene amplification, sequencing
and differential abundance analysis. The hyperaccumulating F. arundinacea rhizosphere microbiome included putative plant growth promoting bacteria (PGPB) and metal tolerance species, such as Rhizorhapis suberifaciens, Cellvibrio fibrivorans and Pseudomonas lini. The rhizosphere microbiome of the fast-growing tree S. miyabeana included diverse taxa involved in POP degradation, including the species Phenylobacterium panacis. The well-characterised nitrogen-fixing M. sativa microbiome species, Sinorhizobium meliloti,
was identified alongside others involved in nutrient acquisition and
putative yet-to-be-cultured Candidatus saccharibacteria (TM7-1 group).
The majority of differentially abundant rhizosphere-associated bacterial
species were maintained in co-cropping pairs, with pairs having higher
numbers of differentially abundant taxa than monocultures in all cases.
This was not the case when all three crops were co-cropped, where most
host-specific bacterial species were not detected as differentially
abundant, indicating the potential for reduced rhizosphere
functionality. The crops cultivated in pairs here retained rhizosphere
microbiome bacteria involved in these monoculture ecosystem services of
plant growth promotion, POP tolerance and degradation, and improved
nutrient acquisition. These findings provide a promising outlook of the
potential for complementary co-cropping strategies for phytoremediation
of the multifaceted anthropogenic pollution which can disastrously
affect soils around the world.
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