Plant mutualisms with rhizosphere microbiota in introduced versus native ranges

Shelby, Natasha; Duncan, Richard P.; Putten, Wim H. van der; McGinn, Kevin; Weser, Carolin; Hulme, Philip E.

doi:10.1111/1365-2745.12609

Cited by 25 publications

(32 citation statements)

References 78 publications

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“…Although the richness of rhizobia strains associated with some species of NZ‐naturalised Trifolium has been shown to be comparable to strain richness in the UK (McGinn et al., ), the effectiveness of rhizobia strains at fixing nitrogen can differ between the introduced and native ranges of legume species (Parker, Wurtz, & Paynter, ), and this could affect the strength and direction of PSF. Indeed, in our previous study, we found that growth rates of some Trifolium species as a factor of rhizobia colonisation were higher when plants were grown in soil from their native range relative to their introduced range (Shelby, Duncan, et al., ). We therefore developed a method to statistically remove the influence of rhizobia on plant growth in order to focus on the effects of other soil biota, such as soil‐borne antagonists and AMF, on plant performance.…”

Section: Methodsmentioning

confidence: 87%

The influence of residence time and geographic extent on the strength of plant–soil feedbacks for naturalised Trifolium

et al. 2017

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Abstract1. Release from natural enemies is considered an important mechanism underlying the success of plants introduced to new regions, but the degree to which alien plant species benefit from enemy release appears highly variable and context-dependent. Such variation could arise if enemy release is a transient phenomenon, whereby alien plant species initially escape but subsequently accumulate enemies in their new regions.2. To evaluate this hypothesis in terms of soil biota, we used 11 Trifolium (clover) species introduced to New Zealand from Europe to test whether species resident for longer or with a larger geographic extent in New Zealand were more adversely affected by soil communities in the introduced range, as expected if species have accumulated inhibitory soil biota over time. We used plant-soil feedback (PSF) experiments to compare the effect of soil biota on the growth of the Trifolium species in soil from their introduced (New Zealand) and native (Spain and the United Kingdom) ranges. We applied a novel statistical approach aimed at isolating the impact of antagonistic soil biota by accounting for variation in plant growth due to mutualistic rhizobia bacteria.3. The between-range differences in PSF varied considerably among the Trifolium species: some species were released from inhibitory PSF in the introduced range, but the majority experienced similar PSF in both ranges. Averaged over all 11 Trifolium species, PSF was less inhibitory in the introduced than in the native range, implying some release from soil-borne enemies. However, neither residence time nor geographic extent in the introduced range was significantly correlated with the strength of release from inhibitory PSF. Synthesis.Our multispecies study provides some evidence that alien plants can escape antagonistic soil biota in their introduced range, but highlights how plant-soil feedback responses can be highly variable among congeneric plant species in the same region. Our results do not support the hypothesis that the release from inhibitory plant-soil feedback is transient, questioning the generality of this phenomenon. K E Y W O R D Salien, biological invasion, enemy release, exotic, invasion ecology, naturalisation, plant-soil (below-ground) interactions, soil biota, weed 208 | Journal of Ecology MCGINN et al.

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Section: Methodsmentioning

confidence: 87%

The influence of residence time and geographic extent on the strength of plant–soil feedbacks for naturalised Trifolium

et al. 2017

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“…Recent work has detected substantial differences in nodule rhizobial communities in the native and non-native ranges of some legumes (e.g. Callaway et al, 2011;Shelby et al, 2016). In these instances, mutualism establishment in the non-native range probably did not involve co-introduction of rhizobia.…”

Section: Review 1355mentioning

confidence: 99%

Co‐introduction vs ecological fitting as pathways to the establishment of effective mutualisms during biological invasions

et al. 2017

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Contents 1354I.1354II.1355III.1357IV.1357V.13591359References1359 Summary Interactions between non‐native plants and their mutualists are often disrupted upon introduction to new environments. Using legume–rhizobium mutualistic interactions as an example, we discuss two pathways that can influence symbiotic associations in such situations: co‐introduction of coevolved rhizobia; and utilization of, and adaptation to, resident rhizobia, hereafter referred to as ‘ecological fitting’. Co‐introduction and ecological fitting have distinct implications for successful legume invasions and their impacts. Under ecological fitting, initial impacts may be less severe and will accrue over longer periods as novel symbiotic associations and/or adaptations may require fine‐tuning over time. Co‐introduction will have more profound impacts that will accrue more rapidly as a result of positive feedbacks between densities of non‐native rhizobia and their coevolved host plants, in turn enhancing competition between native and non‐native rhizobia. Co‐introduction can further impact invasion outcomes by the exchange of genetic material between native and non‐native rhizobia, potentially resulting in decreased fitness of native legumes. A better understanding of the roles of these two pathways in the invasion dynamics of non‐native legumes is much needed, and we highlight some of the exciting research avenues it presents.

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“…In support of novel associations, recent molecular research has demonstrated unique rhizobial communities in association with some legumes in their native versus non-native ranges (e.g. Birnbaum, Barrett, Thrall, & Leishman, 2012;Callaway, Bedmar, Reinhart, Silvan, & Klironomos, 2011;Shelby et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Cointroductions of Australian acacias and their rhizobial mutualists in the Southern Hemisphere

Warrington

Ellis

Novoa

et al. 2019

Journal of Biogeography

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Aim Mutualisms are often disrupted for plants introduced to new ranges, yet many of these plants have managed to obtain effective mutualistic associations in their new ranges. There are two potential pathways for non‐native plants to reassemble mutualisms: cointroduction (i.e. familiar associations with cointroduced mutualists) or ecological fitting (i.e. forming or adapting novel associations with resident native mutualists). We assessed the importance of each pathway for mutualist reassembly in four Australian Acacia species (A. baileyana, A. dealbata, A. decurrens and A. melanoxylon) and their associated nitrogen‐fixing rhizobial symbionts in two non‐native locations. Location Native ranges of acacias in south‐eastern Australia and two non‐native ranges in New Zealand and South Africa. Methods Rhizobia associated with each acacia species in each country were isolated and identified based on DNA sequencing of the housekeeping recA gene and the symbiotic nodA gene. Separate phylogenies were reconstructed for each gene region to infer biogeographic histories of acacia‐associated rhizobia. Selected rhizobial strains for each acacia species by country combination were used as inocula in a glasshouse experiment and early growth kinetics and nitrogen fixation efficiency of acacia seedlings were compared between inoculum treatments to determine symbiotic effectiveness. Results All isolated rhizobial strains belonged to the genus Bradyrhizobium. Phylogenetic analyses revealed almost no country‐ or species‐specific clusters of these strains for either gene region and indicated that most acacia‐associated bradyrhizobia in New Zealand and South Africa were cointroduced from Australia. These results were supported by little variation in the growth performances of acacia seedlings, irrespective of inoculum treatment. Main conclusions This study revealed that cointroduction of Australian acacias and their rhizobia may be more prevalent than previously thought. Additionally, a single rhizobium cointroduction event may be sufficient to facilitate the establishment of effective mutualisms in numerous Acacia species, potentially leading to an invasion meltdown.

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Plant mutualisms with rhizosphere microbiota in introduced versus native ranges

Cited by 25 publications

References 78 publications

The influence of residence time and geographic extent on the strength of plant–soil feedbacks for naturalised Trifolium

The influence of residence time and geographic extent on the strength of plant–soil feedbacks for naturalised Trifolium

Co‐introduction vs ecological fitting as pathways to the establishment of effective mutualisms during biological invasions

Cointroductions of Australian acacias and their rhizobial mutualists in the Southern Hemisphere

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