Plant-growth-promoting Caulobacter strains isolated from distinct plant hosts share conserved genetic factors involved in beneficial plant-bacteria interactions

Identity and timing of protist inoculation affect plant performance largely irrespective of changes in the rhizosphere microbial community

Bacterivorous soil protists can have positive impacts on plant performance, making them attractive targets for novel strategies to improve crop production. However, we generally lack the knowledge required to make informed choices regarding the protist species to be used or the optimal conditions for such amendments. Here, we examined how identity, diversity, and timing of inoculation of well-described protists impacted plant development and rhizosphere microbiome assembly. We first studied the impact of individual inoculation of six well-characterized protists on lettuce growth, with Cercomonas sp. S24D2 emerging as the strain with the largest impact on plant growth. In a second step, we created a three-protist species mixture inoculant by adding two protist species (Acanthamoeba sp. C13D2 and a heterolobosean isolate S18D10), based on differences in their feeding patterns. We then inoculated Cercomonas sp. either individually or in the protist mixture to lettuce plants 1 week before, simultaneously with, or 1 week after seedling transfer. We monitored plant growth and nutrient content, as well as impacts on the resident soil and rhizosphere microbiome composition. We found that early protist inoculation provided the greatest increase in aboveground biomass compared to the non-inoculated control. Single- and mixed-species inoculations had similar impacts on plant development and only minor impacts on prokaryotic community composition. While early inoculation seems to be the most promising timing for eliciting the positive effects of protist amendments, further, more systematic studies will be necessary to determine the conditions and ecological interactions that yield consistent and predictable improvements in plant performance.

IMPORTANCE

The application of microorganisms, including bacterivorous soil protists, has been increasingly suggested as a sustainable agricultural approach. While positive impacts of the presence of predatory protists have been generally reported, the effects of the selected species and amendment conditions are largely unknown. Here, we examined how identity, diversity, and timing of inoculation of well-described protists impacted plant development and rhizosphere microbiome assembly. One species emerged as the one having the strongest impact in our specific system. This result highlights the importance of species selection for optimal outcome, but also suggests a huge potential in the barely investigated protist diversity for targeted application. Furthermore, the application of the inoculants before plant transfer showed the strongest effects on plants, providing some useful and new insights on the optimal time for such amendments.

Standardizing experimental approaches to investigate interactions between bacteria and ectomycorrhizal fungi

Bacteria and ectomycorrhizal fungi (EcMF) represent two of the most dominant plant root-associated microbial groups on Earth, and their interactions continue to gain recognition as significant factors that shape forest health and resilience. Yet, we currently lack a focused review that explains the state of bacteria-EcMF interaction research in the context of experimental approaches and technological advancements. To these ends, we illustrate the utility of studying bacteria-EcMF interactions, detail outstanding questions, outline research priorities in the field, and provide a suite of approaches that can be used to promote experimental reproducibility, field advancement, and collaboration. Though this review centers on the ecology of bacteria, EcMF, and trees, it by default offers experimental and conceptual insights that can be adapted to various subfields of microbiology and microbial ecology.

Bacterial wilt suppressive composts: Significance of rhizosphere microbiome

Composts are often suppressive to several plant diseases, including the devastating bacterial wilt caused by Ralstonia solanacearum. However, the underlying mechanisms are still unclear. Herein, we carried out an experiment with 38 composts collected from different factories in China to study the interlinking among bacterial wilt suppression, the physicochemical properties and bacterial community of the compost, and bacterial community in the rhizosphere of tomato fertilized by compost. Totally 26 composts were suppressive to bacterial wilt, while six composts stimulated the disease. The control efficiency was neither correlated with physicochemical properties (TC, TN, P and K, pH or GI) nor bacterial community of compost, but with rhizosphere bacterial community (r = 0.17, p = 0.016). The control efficiency was also positive correlated with taxa (Rhizobium, Aeromicrobium) known suppressive to R. solanacearum. The mushroom spent or cow manure, from which the two composts were 100% and 77% in control efficiencies against bacterial wilt respectively were subject to a pilot-scale composting reaction. The reproduced composts from mushroom spent or cow manure were only 57% and 23% effective on the control of bacterial wilt, respectively. The analysis of bacterial communities revealed that the relative abundances of R. solanacearum were 28.4% for the control, but only 7.8%-7.9% for compost fertilized tomatoes. The compost from mushroom spent also exerted a strong effect on rhizosphere bacterial community. Taken together, most composts were suppressive to bacterial wilt possibly also by modifying rhizosphere bacterial community towards inhibiting the colonization of R. solanacearum and selecting for beneficial genera of Proteobacteria, Bacteroidetes and Actinobacteria.

Current Techniques to Study Beneficial Plant-Microbe Interactions

Many different experimental approaches have been applied to elaborate and study the beneficial interactions between soil bacteria and plants. Some of these methods focus on changes to the plant and others are directed towards assessing the physiology and biochemistry of the beneficial plant growth-promoting bacteria (PGPB). Here, we provide an overview of some of the current techniques that have been employed to study the interaction of plants with PGPB. These techniques include the study of plant microbiomes; the use of DNA genome sequencing to understand the genes encoded by PGPB; the use of transcriptomics, proteomics, and metabolomics to study PGPB and plant gene expression; genome editing of PGPB; encapsulation of PGPB inoculants prior to their use to treat plants; imaging of plants and PGPB; PGPB nitrogenase assays; and the use of specialized growth chambers for growing and monitoring bacterially treated plants.

Examining the genomic features of human and plant-associated Burkholderia strains

Humans and plants have evolved in the near omnipresence of a microbial milieu, and the factors that govern host-microbe interactions continue to require scientific exploration. To better understand if and to what degree patterns between microbial genomic features and host association (i.e., human and plant) exist, I analyzed the genomes of select Burkholderia strains-a bacterial genus comprised of both human and plant-associated strains-that were isolated from either humans or plants. To this end, I uncovered host-specific, genomic patterns related to metabolic pathway potentials in addition to convergent features that may be related to pathogenic overlap between hosts. Together, these findings detail the genomic associations of human and plant-associated Burkholderia strains and provide a framework for future investigations that seek to link host-host transmission potentials.

The genus Caulobacter and its role in plant microbiomes

Recent omics approaches have revealed the prevalent microbial taxa that constitute the microbiome of various plant species. Across global scales and environmental conditions, strains belonging to the bacterial genus Caulobacter have consistently been found in association with various plant species. Aligned with agroecological relevance and biotechnological advances, many scientific communications have demonstrated that several Caulobacter strains (spanning several Caulobacter species) harbor the potential to enhance plant biomass for various plant species ranging from Arabidopsis to Citrullus and Zea mays. In the past several years, co-occurrence data have driven mechanistically resolved communications about select Caulobacter-plant interactions. Given the long-standing history of Caulobacter as a model organism for cell cycle regulation, genetic studies, and the prevalence of Caulobacter species in various plant microbiomes, the genus Caulobacter offers researchers a unique opportunity to leverage for investigating plant-microbe interactions and realizing targeted biotechnological applications. In this review, recent developments regarding Caulobacter-plant interactions are presented in terms of model utility for future biotechnological investigations.