Competition, Nodule Occupancy, and Persistence of Inoculant Strains: Key Factors in the Rhizobium-Legume Symbioses

Mendoza-Suárez, Marcela; Andersen, Stig U.; Poole, Philip S.; Sánchez-Cañizares, Carmen

doi:10.3389/fpls.2021.690567

Cited by 66 publications

(56 citation statements)

References 331 publications

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“…At this stage, we cannot distinguish between two hypotheses, namely if these mutations do not exist (proliferation is always linked to nodulation and host entry) or if they were not yet selected in this experiment due to the dominance of nodulation competitiveness in the first steps of adaptation. Future functional analyses of the adaptive mutations identified in this study will expand our understanding of the molecular bases of nodulation competitiveness in rhizobia [65][66][67] , and its relationship to within-host proliferation. Interestingly, these two traits primarily selected by the plant, although necessary for the symbiotic interaction, are not, in themselves, beneficial for the host.…”

Section: Discussionmentioning

confidence: 92%

“…Moreover the identification of plant receptors (LYK3, NFR1, Sym37, SYMRK) and transcription factors (NIN, ERN1, ERN2) involved in both nodule organogenesis and rhizobial intracellular infection [67][68][69][70] supports the existence of common mechanisms controlling the two processes on the plant side. Future functional analyses of the adaptive mutations identified in this study will expand our understanding of the molecular bases of nodulation competitiveness in rhizobia 60,71,72 , and its relationship to within-host proliferation. Including mutualistic traits (nitrogen fixation and host growth promotion) in the analysis of the genetic couplings (or trade-offs) between the different symbiotic traits will be important to fully characterize the genetic constraints shaping the evolution of rhizobium-legume interactions [72][73][74] .…”

Section: Discussionmentioning

confidence: 92%

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A selective bottleneck during host entry drives the evolution of new legume symbionts

Moura

Mouffok

Gaudu

et al. 2022

Preprint

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During the emergence of new host-microbe symbioses, multiple selective pressures –acting at the different steps of the microbial life cycle– will shape the phenotypic traits that jointly determine microbial fitness. However, the relative contribution of these different selective pressures on the adaptive trajectories of microbial symbionts are still poorly known. Here we characterized the dynamics of phenotypic adaptation and the underlying genetic bases during the experimental evolution of a plant pathogenic bacterium into a legume symbiont. We show that fast adaptation was supported by the sequential fixation of mutational cohorts within populations, and dominated by selection for host entry competitiveness over within-host proliferation. Computer simulations predict that this effect emerges from the presence of a strong selective bottleneck at host entry before bacterial multiplication. However, identifying and characterizing adaptive mutations revealed recurrent couplings between the two phenotypic traits, further increasing the efficiency of host-mediated selection of new symbionts.

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Section: Discussionmentioning

confidence: 92%

Section: Discussionmentioning

confidence: 92%

A selective bottleneck during host entry drives the evolution of new legume symbionts

Moura

Mouffok

Gaudu

et al. 2022

Preprint

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“…Two inoculation methods suitable for field planting, alginate and 12 h coating were tested under field condition but only a negligible amount of inoculated bacteria were detected in the rhizosphere. This may have been because the bacterial isolate concentration used to coat the seeds (10 3 -10 4 CFU per seed) was too low to facilitate their establishment in sorghum rhizosphere under non-sterile conditions where there is competition from the natural microbial communities (Mendoza-Suárez et al, 2021). Although a standard of 10 4 rhizobial cells per seed is widely used to inoculate legumes with medium-size seed (e.g., mung bean and pigeon pea) like sorghum (Lupwayi et al, 2000), this may not be applicable for the inoculation of non-rhizobia species and for non-legumes.…”

Section: Discussionmentioning

confidence: 99%

Assessment of Bacterial Inoculant Delivery Methods for Cereal Crops

2022

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Despite growing evidence that plant growth-promoting bacteria can be used to improve crop vigor, a comparison of the different methods of delivery to determine which is optimal has not been published. An optimal inoculation method ensures that the inoculant colonizes the host plant so that its potential for plant growth-promotion is fully evaluated. The objective of this study was to compare the efficacy of three seed coating methods, seedling priming, and soil drench for delivering three bacterial inoculants to the sorghum rhizosphere and root endosphere. The methods were compared across multiple time points under axenic conditions and colonization efficiency was determined by quantitative polymerase chain reaction (qPCR). Two seed coating methods were also assessed in the field to test the reproducibility of the greenhouse results under non-sterile conditions. In the greenhouse seed coating methods were more successful in delivering the Gram-positive inoculant (Terrabacter sp.) while better colonization from the Gram-negative bacteria (Chitinophaga pinensis and Caulobacter rhizosphaerae) was observed with seedling priming and soil drench. This suggested that Gram-positive bacteria may be more suitable for the seed coating methods possibly because of their thick peptidoglycan cell wall. We also demonstrated that prolonged seed coating for 12 h could effectively enhance the colonization of C. pinensis, an endophytic bacterium, but not the rhizosphere colonizing C. rhizosphaerae. In the field only a small amount of inoculant was detected in the rhizosphere. This comparison demonstrates the importance of using the appropriate inoculation method for testing different types of bacteria for their plant growth-promotion potential.

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“…Although an elite strain with a high and consistent PS activity is an essential prerequisite for the development of successful inoculant, the non-biological components for bioformulations are still key bottlenecks in commercial development of the inoculants (Mendoza-Suárez et al, 2021 ). The choice of carrier material is fundamental, because carrier is the sole delivery vehicle of live microorganism from the production unit to the plants in the field (Vassilev et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Designing Synergistic Biostimulants Formulation Containing Autochthonous Phosphate-Solubilizing Bacteria for Sustainable Wheat Production

et al. 2022

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Applying phosphate-solubilizing bacteria (PSB) as biofertilizers has enormous potential for sustainable agriculture. Despite this, there is still a lack of information regarding the expression of key genes related to phosphate-solubilization (PS) and efficient formulation strategies. In this study, we investigated rock PS by Ochrobactrum sp. SSR (DSM 109610) by relating it to bacterial gene expression and searching for an efficient formulation. The quantitative PCR (qPCR) primers were designed for PS marker genes glucose dehydrogenase (gcd), pyrroloquinoline quinone biosynthesis protein C (pqqC), and phosphatase (pho). The SSR-inoculated soil supplemented with rock phosphate (RP) showed a 6-fold higher expression of pqqC and pho compared to inoculated soil without RP. Additionally, an increase in plant phosphorous (P) (2%), available soil P (4.7%), and alkaline phosphatase (6%) activity was observed in PSB-inoculated plants supplemented with RP. The root architecture improved by SSR, with higher root length, diameter, and volume. Ochrobactrum sp. SSR was further used to design bioformulations with two well-characterized PS, Enterobacter spp. DSM 109592 and DSM 109593, using the four organic amendments, biochar, compost, filter mud (FM), and humic acid. All four carrier materials maintained adequate survival and inoculum shelf life of the bacterium, as indicated by the field emission scanning electron microscopy analysis. The FM-based bioformulation was most efficacious and enhanced not only wheat grain yield (4–9%) but also seed P (9%). Moreover, FM-based bioformulation enhanced soil available P (8.5–11%) and phosphatase activity (4–5%). Positive correlations were observed between the PSB solubilization in the presence of different insoluble P sources, and soil available P, soil phosphatase activity, seed P content, and grain yield of the field grown inoculated wheat variety Faisalabad-2008, when di-ammonium phosphate fertilizer application was reduced by 20%. This study reports for the first time the marker gene expression of an inoculated PSB strain and provides a valuable groundwork to design field scale formulations that can maintain inoculum dynamics and increase its shelf life. This may constitute a step-change in the sustainable cultivation of wheat under the P-deficient soil conditions.

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Competition, Nodule Occupancy, and Persistence of Inoculant Strains: Key Factors in the Rhizobium-Legume Symbioses

Cited by 66 publications

References 331 publications

A selective bottleneck during host entry drives the evolution of new legume symbionts

A selective bottleneck during host entry drives the evolution of new legume symbionts

Assessment of Bacterial Inoculant Delivery Methods for Cereal Crops

Designing Synergistic Biostimulants Formulation Containing Autochthonous Phosphate-Solubilizing Bacteria for Sustainable Wheat Production

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