Jonathan R. Gaiero scite author profile

Bacterial root endophytes reside in a vast number of plant species as part of their root microbiome, with some being shown to positively influence plant growth. Endophyte community structure (species diversity: richness and relative abundances) within the plant is dynamic and is influenced by abiotic and biotic factors such as soil conditions, biogeography, plant species, microbe-microbe interactions and plant-microbe interactions, both at local and larger scales. Plant-growth-promoting bacterial endophytes (PGPBEs) have been identified, but the predictive success at positively influencing plant growth in field conditions has been limited. Concurrent to the development of modern molecular techniques, the goal of predicting an organism's ability to promote plant growth can perhaps be realized by more thorough examination of endophyte community dynamics. This paper reviews the drivers of endophyte community structure relating to plant growth promotion, the mechanisms of plant growth promotion, and the current and future use of molecular techniques to study these communities.

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Quantification of bacterial non-specific acid ( phoC) and alkaline ( phoD ) phosphatase genes in bulk and rhizosphere soil from organically managed soybean fields

Fraser

Lynch

Gaiero

et al. 2017

Applied Soil Ecology

144

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It takes three to tango: the importance of microbes, host plant, and soil management to elucidate manipulation strategies for the plant microbiome

et al. 2020

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The world’s population is expected to grow to almost 10 billion by 2050, placing unprecedented demands on agriculture and natural resources. The risk in food security is also aggravated by climate change and land degradation, which compromise agricultural productivity. In recent years, our understanding of the role of microbial communities on ecosystem functioning, including plant-associated microbes, has advanced considerably. Yet, translating this knowledge into practical agricultural technologies is challenged by the intrinsic complexity of agroecosystems. Here, we review current strategies for plant microbiome manipulation, classifying them into three main pillars: (i) introducing and engineering microbiomes, (ii) breeding and engineering the host plant, and (iii) selecting agricultural practices that enhance resident soil and plant-associated microbial communities. In each of these areas, we analyze current trends in research, as well as research priorities and future perspectives.

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Validating novel oligonucleotide primers targeting three classes of bacterial non-specific acid phosphatase genes in grassland soils

et al. 2017

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Bacterial Endophytes: Diversity, Functional Importance, and Potential for Manipulation

Tosi

Gaiero

Linton

et al. 2020

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Effect of long-term plant biomass management on phosphatase-producing bacterial populations in soils under temperate grassland

Gaiero

Bent

Boitt

et al. 2020

Applied Soil Ecology

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Soil microbial communities influencing organic phosphorus mineralization in a coastal dune chronosequence in New Zealand

Gaiero

Tosi

Bent

et al. 2021

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The Haast chronosequence in New Zealand is a ∼6500-year dune formation series, characterized by rapid podzol development, phosphorus (P) depletion, and a decline in aboveground biomass. We examined bacterial and fungal community composition within mineral soil fractions using amplicon-based high-throughput sequencing (Illumina MiSeq). We targeted bacterial non-specific acid (class A, phoN/phoC) and alkaline (phoD) phosphomonoesterase genes and quantified specific genes and transcripts using real-time PCR. Soil bacterial diversity was greatest after 4000 years of ecosystem development and associated with an increased richness of phylotypes and a significant decline in previously dominant taxa (Firmicutes and Proteobacteria). Soil fungal communities transitioned from predominantly Basidiomycota to Ascomycota along the chronosequence and were most diverse in 290 to 392-year-old soils, coinciding with maximum tree basal area and organic P accumulation. The Bacteria: Fungi ratio decreased amid a competitive and interconnected soil community as determined by network analysis. Overall, soil microbial communities were associated with soil changes and declining P throughout pedogenesis and ecosystem succession. We identified an increased dependence on organic P mineralization, as found by the profiled acid phosphatase genes, soil acid phosphatase activity, and function inference from predicted metagenomes (PICRUSt2).

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Draft Genome Sequence of Ureolytic Environmental Isolate Staphylococcus sp. NA309

et al. 2016

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