Rhizosphere Microbiomes of Amaranthus spp. Grown in Soils with Anthropogenic Polyelemental Anomalies

Study of rhizospheric microbial communities of plants growing under different environmental conditions is important for understanding the habitat-dependent formation of rhizosphere microbiomes. The rhizosphere bacterial communities of four amaranth cultivars were investigated in a laboratory pot experiment. Amaranthus tricolor cv. Valentina, A. cruentus cv. Dyuimovochka, and A. caudatus cvs. Bulava and Zelenaya Sosulka were grown for six months in three soils with different anthropogenic polyelemental anomalies and in a background control soil. After the plant cultivation, the rhizosphere soils were sampled and subjected to metagenomic analysis for the 16S rRNA gene. The results showed that the taxonomic structure of the amaranth rhizosphere microbiomes was represented by the dominant bacterial phyla Actinobacteriota and Proteobacteria. A feature of the taxonomic profile of the rhizobiomes of A. tricolor cv. Valentina and A. cruentus cv. Dyuimovochka was a large abundance of sequences related to Cyanobacteria. The formation of the amaranth rhizosphere microbiomes was largely unaffected by soils, but cultivar differences in the formation of the amaranth rhizosphere microbial structure were revealed. Bacterial taxa were identified that are possibly selected by amaranths and that may be important for plant adaptation to various habitat conditions. The targeted enrichment of the amaranth rhizosphere with members of these taxa could be useful for improving the efficacy of amaranth use for agricultural and remediation purposes.

[1]  Sooyeon Lee,et al.  Effect of Novosphingobium sp. CuT1 inoculation on the rhizoremediation of heavy metal- and diesel-contaminated soil planted with tall fescue , 2022, Environmental Science and Pollution Research.

[2]  M. Frontasyeva,et al.  Phytoextraction of toxic elements by Amaranthus Tricolor grown on technogenically polluted soils in open ground conditions , 2022, Chimica Techno Acta.

[3]  E. Allen,et al.  Defining and quantifying the core microbiome: Challenges and prospects , 2021, Proceedings of the National Academy of Sciences.

[4]  A. Barra Caracciolo,et al.  Rhizosphere Microbial Communities and Heavy Metals , 2021, Microorganisms.

[5]  Zhaojin Chen,et al.  Responses of rhizosphere bacterial communities, their functions and their network interactions to Cd stress under phytostabilization by Miscanthus spp. , 2021, Environmental pollution.

[6]  Xiaoxu Sun,et al.  Root-associated (rhizosphere and endosphere) microbiomes of the Miscanthus sinensis and their response to the heavy metal contamination. , 2021, Journal of environmental sciences.

[7]  S. Strauss,et al.  Insights into the taxonomic and functional characterization of agricultural crop core rhizobiomes and their potential microbial drivers , 2021, Scientific Reports.

[8]  Plant, Soil and Microbes in Tropical Ecosystems , 2021, Rhizosphere Biology.

[9]  Omics Science for Rhizosphere Biology , 2021 .

[10]  M. Frontasyeva,et al.  Toxic Elements in the Soils of Urban Ecosystems and Technogenic Sources of Pollution , 2020, WSEAS TRANSACTIONS ON ENVIRONMENT AND DEVELOPMENT.

[11]  Y. Yoshikuni,et al.  Microbiome Engineering: Synthetic Biology of Plant-Associated Microbiomes in Sustainable Agriculture. , 2020, Trends in biotechnology.

[12]  Ashwani Kumar,et al.  Rhizosphere microbiome: Engineering bacterial competitiveness for enhancing crop production , 2020, Journal of advanced research.

[13]  J. A. López-González,et al.  Prospection of cyanobacteria producing bioactive substances and their application as potential phytostimulating agents , 2020, Biotechnology reports.

[14]  M. Meena,et al.  Cyanobacteria as a source of biofertilizers for sustainable agriculture , 2020, Biochemistry and biophysics reports.

[15]  A. Al-Harrasi,et al.  Sphingomonas: from diversity and genomics to functional role in environmental remediation and plant growth , 2020, Critical reviews in biotechnology.

[16]  A. Muratova,et al.  Rhizospheric microbiomes of Sorghum bicolor grown on soils with anthropogenic polyelement anomalies , 2020, BIO Web of Conferences.

[17]  A. Singh,et al.  Kinetics of hydrocarbon degradation by a newly isolated heavy metal tolerant bacterium Novosphingobium panipatense P5:ABC. , 2019, Bioresource technology.

[18]  B. Odiyi,et al.  Phytoremediation potential of Amaranthus hybridus L. (Caryophyllales: Amaranthaceae) on soil amended with brewery effluent , 2019, Brazilian Journal of Biological Sciences.

[19]  William A. Walters,et al.  Reproducible, interactive, scalable and extensible microbiome data science using QIIME 2 , 2019, Nature Biotechnology.

[20]  Praveen Kumar,et al.  Rhizosphere microbiome: revisiting the synergy of plant-microbe interactions , 2019, Annals of Microbiology.

[21]  Anil Kumar,et al.  Plant Growth Promoting Rhizobacteria for Agricultural Sustainability , 2019, Springer Singapore.

[22]  N. Thajuddin,et al.  Evaluation and characterization of the plant growth promoting potentials of two heterocystous cyanobacteria for improving food grains growth , 2019, Biocatalysis and Agricultural Biotechnology.

[23]  R. Qiu,et al.  Structural development and assembly patterns of the root-associated microbiomes during phytoremediation. , 2018, The Science of the total environment.

[24]  N. Pérez,et al.  Enzymatic activity and culturable bacteria diversity in rhizosphere of amaranth, as indicators of crop phenological changes , 2018, Botanical Sciences.

[25]  Di Fan,et al.  Isolation and diversity of culturable rhizobacteria associated with economically important crops and uncultivated plants in Québec, Canada. , 2018, Systematic and applied microbiology.

[26]  M. Häggblom,et al.  Rhizosphere Microbial Response to Multiple Metal(loid)s in Different Contaminated Arable Soils Indicates Crop-Specific Metal-Microbe Interactions , 2018, Applied and Environmental Microbiology.

[27]  P. Ahmad,et al.  Plant Microbiome: Stress Response , 2018, Microorganisms for Sustainability.

[28]  Olubukola Oluranti Babalola,et al.  Microbial and Plant-Assisted Bioremediation of Heavy Metal Polluted Environments: A Review , 2017, International journal of environmental research and public health.

[29]  Zengqiang Zhang,et al.  Role of Streptomyces pactum in phytoremediation of trace elements by Brassica juncea in mine polluted soils. , 2017, Ecotoxicology and environmental safety.

[30]  N. Arora,et al.  Alleviation of Heavy Metal Stress in Plants and Remediation of Soil by Rhizosphere Microorganisms , 2017, Front. Microbiol..

[31]  Pratima Gupta,et al.  Bacterial Exopolysaccharide mediated heavy metal removal: A Review on biosynthesis, mechanism and remediation strategies , 2016, Biotechnology reports.

[32]  E. Banchio,et al.  Roles of Extracellular Polysaccharides and Biofilm Formation in Heavy Metal Resistance of Rhizobia , 2016, Materials.

[33]  Paul J. McMurdie,et al.  DADA2: High resolution sample inference from Illumina amplicon data , 2016, Nature Methods.

[34]  G. Moreno-Hagelsieb,et al.  Plant growth-promoting bacterial endophytes. , 2016, Microbiological research.

[35]  Huaping Li,et al.  Massilia putida sp. nov., a dimethyl disulfide-producing bacterium isolated from wolfram mine tailing. , 2016, International journal of systematic and evolutionary microbiology.

[36]  Zhi Zhou,et al.  Anthropogenic impact on diazotrophic diversity in the mangrove rhizosphere revealed by nifH pyrosequencing , 2015, Front. Microbiol..

[37]  M. Turmel,et al.  Early rhizosphere microbiome composition is related to the growth and Zn uptake of willows introduced to a former landfill. , 2015, Environmental microbiology.

[38]  Xiaoe Yang,et al.  Improvement of cadmium uptake and accumulation in Sedum alfredii by endophytic bacteria Sphingomonas SaMR12: effects on plant growth and root exudates. , 2014, Chemosphere.

[39]  Y. Hadar,et al.  Niche and host-associated functional signatures of the root surface microbiome , 2014, Nature Communications.

[40]  H. Heuer,et al.  Effect of the soil type on the microbiome in the rhizosphere of field-grown lettuce , 2014, Front. Microbiol..

[41]  P. Ziarati,et al.  The Phytoremediation Technique for Cleaning up Contaminated Soil By Amaranthus sp. , 2014 .

[42]  Pelin Yilmaz,et al.  The SILVA and “All-species Living Tree Project (LTP)” taxonomic frameworks , 2013, Nucleic Acids Res..

[43]  Rodrigo Mendes,et al.  The rhizosphere microbiome: significance of plant beneficial, plant pathogenic, and human pathogenic microorganisms. , 2013, FEMS microbiology reviews.

[44]  B. Oh,et al.  Enhancement of heavy metal phytoremediation by Alnus firma with endophytic Bacillus thuringiensis GDB-1. , 2013, Journal of hazardous materials.

[45]  T. Sengupta,et al.  Biofilm-Mediated Enhanced Crude Oil Degradation by Newly Isolated Pseudomonas Species , 2013, ISRN biotechnology.

[46]  A. Klindworth,et al.  Evaluation of general 16S ribosomal RNA gene PCR primers for classical and next-generation sequencing-based diversity studies , 2012, Nucleic acids research.

[47]  A. Chubey Rhizobia Unique Plant Growth Promoting Rhizobacteria: A Review , 2013 .

[48]  Ximei Zhang,et al.  Elevated CO2 increases Cs uptake and alters microbial communities and biomass in the rhizosphere of Phytolacca americana Linn (pokeweed) and Amaranthus cruentus L. (purple amaranth) grown on soils spiked with various levels of Cs. , 2012, Journal of environmental radioactivity.

[49]  Robert C. Edgar,et al.  Defining the core Arabidopsis thaliana root microbiome , 2012, Nature.

[50]  M. Chinmayee,et al.  The Assessment of Phytoremediation Potential of Invasive Weed Amaranthus spinosus L. , 2012, Applied Biochemistry and Biotechnology.

[51]  C. B. Chikere,et al.  Monitoring of microbial hydrocarbon remediation in the soil , 2011, 3 Biotech.

[52]  V. Kuznetsov,et al.  Phytoremediation potential of Amaranthus hybrids: Antagonism between nickel and iron and chelating role of polyamines , 2011, Russian Journal of Plant Physiology.

[53]  R. Prasanna,et al.  Rhizosphere dynamics of inoculated cyanobacteria and their growth-promoting role in rice crop. , 2009 .

[54]  B. Ginn,et al.  Cd adsorption onto Pseudomonas putida in the presence and absence of extracellular polymeric substances , 2008 .

[55]  J. Vivanco,et al.  Root Exudates Modulate Plant—Microbe Interactions in the Rhizosphere , 2008 .

[56]  Zhenli He,et al.  Role of soil rhizobacteria in phytoremediation of heavy metal contaminated soils , 2007, Journal of Zhejiang University SCIENCE B.

[57]  J. Maldonado,et al.  Isolation and Characterization of a Heterotrophic Bacterium Able to Grow in Different Environmental Stress Conditions, Including Crude Oil and Heavy Metals , 2007 .

[58]  G. Preston Plant perceptions of plant growth-promoting Pseudomonas. , 2004, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[59]  P. Lindblad,et al.  Cyanobacteria in symbiosis with cycads. , 2002 .

[60]  B. Bergman,et al.  The Nostoc-Gunnera symbiosis. , 1992, The New phytologist.