Evidence for scale-dependent root-augmentation feedback and its role in halting the spread of a pantropical shrub into an endemic sedge

Bennett, Jamie J. R.; Gomes, Anabele Stefânia; Ferré, Michel; Bera, Bidesh K.; Borghetti, Fabian; Callaway, Ragan M.; Meron, Ehud

doi:10.1093/pnasnexus/pgac294

Cited by 4 publications

(5 citation statements)

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“…The apparent spatial similarity between NFC patterns and AFC patterns (Figure 1a-c) has been attributed to the same general positive feedback that both systems share, a scale-dependent feedback between local vegetation growth and water transport to the growth location [15,30], albeit with diff erent water transport mechanisms [2,16,31]. NFCs patterns form in deep aeolian sands, characterized by high water infi ltration rates.…”

Section: Introductionmentioning

confidence: 83%

“…Another possible implication of our fi ndings is related to the multi-scale nature of patterns is related to the multi-scale nature of patterns observed in Namibian and Australian FCs-largescale FC patterns and small-scale patterns within the scale FC patterns and small-scale patterns within the vegetation matrix. In NFCs, the small-scale pattern often consists of spots [9,31], whereas in AFCs, it consists mostly of rings (Figure 1d) [2]. Vegetation rings have commonly been explained by negative plant-soil feedbacks [23,45] and by plant-water scale-dependent feedbacks [46][47][48][49][50][51].…”

Section: Discussionmentioning

confidence: 99%

“…NFCs patterns form in deep aeolian sands, characterized by high water infi ltration rates. The water-transport mechanism, in this case, is soil-water lateral diff usion towards denser and, thus, drier vegetation patches [5,31,32] and the soil water content is on average higher in the center then in the fairy circle periphery. By contrast, in Australia, the top soil layer is a barely permeable claypan that generates overland water fl ow towards denser vegetation patches at the gap edges (Figures 2a,3c) [2,3,14] and the soil water content in the center of the AFC is lower than in the periphery.…”

Section: Introductionmentioning

confidence: 93%

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Microbial Factors May Contribute to the Persistence of Australian Fairy Circles

Klipcan,

Kamennaya,

Than Aye

et al. 2024

J Biomed Res Environ Sci

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Fairy Circles (FCs) are roughly circular, spatially periodic barren patches occurring both along the southwestern African coast, spanning the Namib Desert (NFCs), and in the Pilbara region of Western Australia (AFCs). The origin of both NFC and AFC patterns is still debatable and a subject of ongoing research. Recently, it was argued that pathogenic soil microbes may contribute to ring formation of the Triodia basedowii grass which is the same grass species that forms the AFCs. We have analyzed, under controlled laboratory conditions, soil samples taken from different parts of AFCs (center, periphery and m3atrix) for microbiological activities by Lettuce germination experiments under different manipulations. In seven different circles, out of an average of 13, root lengths of germinated seeds were strongly inhibited in the samples taken from the center, and to a lesser extent, in the samples taken from the periphery and the matrix. Quantitative analyses of the soil microbial community from the FC center found no support to the hypothesis that phytotoxic effect was caused by soil crust cyanobacteria due their low abundance. However, in soil of the FCs it identified both heterotrophic bacteria and fungi that may contribute to the phytotoxic effect. Although our study was not done with seeds of Triodia basedowii it supports the idea that microbial activities in the soil may contribute to AFC persistence by inhibiting plant germination and development in the bare soil gaps in addition to the physical soil crusts resulting from weathering. This suggests that negative plant-soil feedback can act in concert with the main driver mechanism of the AFCs, the scale-dependent plant-water feedback.

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Section: Introductionmentioning

confidence: 83%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 93%

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Microbial Factors May Contribute to the Persistence of Australian Fairy Circles

Klipcan,

Kamennaya,

Than Aye

et al. 2024

J Biomed Res Environ Sci

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“…There, the formation of a spatial pattern can promote coexistence between (autotrophic) consumer species that differ in their dispersal strategies (Nathan et al, 2013; Eigentler and Sherratt, 2020) or through relaxing competition and even enabling facilitation between species in the emergent heterogeneous environmental conditions (Cornacchia et al, 2018; L. Eigentler, 2021; Bennett et al, 2023). These studies however neglect the fragmentation of many natural landscapes into discrete habitat patches that may be only partially connected by dispersal links and therefore often have irregular spatial structures (Holland and Hastings, 2008).…”

Section: Introductionmentioning

confidence: 99%

Habitat isolation diminishes potential of self-organised pattern formation to promote local diversity in metacommunities

Philipp,

Klauschies,

Guill

2024

Preprint

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Progressive destruction and isolation of natural habitat is a major threat to biodiversity worldwide. In this study we use a trophic metacommunity model with complex, spatially explicit structure to address how the interaction of local and regional processes affects the functional diversity of autotroph (producer) communities within and between individual habitat patches. One important driver of biodiversity in metacommunities is spatial heterogeneity of the environment, as it enables source-sink dynamics between patches. Besides a-priori differences in the environmental conditions, heterogeneous distributions of resources and species biomasses can also emerge through self-organised pattern formation caused by scale-dependent feedback between local trophic and regional dispersal dynamics. We show that this emergent heterogeneity can enhance the functional diversity of local autotroph communities by jointly strengthening source-sink dynamics and reducing stabilising selection pressure. Our results indicate that this effect is particularly strong in highly connected metacommunities, while metacommunity size (number of patches) alone plays a lesser role. We demonstrate that the positive effect on local diversity is driven by an eco-evo-spatial feedback loop that is fueled by the asynchronous biomass- and trait dynamics between the patches created by self-organised pattern formation. In highly connected metacommunities, oscillatory biomass patterns with particularly large amplitude strengthen this feedback loop. Our findings are highly relevant in the light of anthropogenic habitat changes that often destroy dispersal pathways, thereby increasing habitat isolation, lowering overall connectance of metacommunities and ultimately threatening the biodiversity in local habitats. Only a joint investigation of the contributing ecological, evolutionary, and spatial mechanisms in complex model systems can yield comprehensive understanding of these processes, allowing for the development of strategies to mitigate adverse anthropogenic influence.

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“…Observations of vegetation patterns have primarily been reported in drylands ( 1 – 4 ), which occupy more than two-fifths of the terrestrial earth area and are expected to expand as climate change proceeds ( 5 ), but are not limited to drylands ( 6 – 9 ). Pattern formation theory ( 10 – 13 ) has been highly instrumental in understanding the emergence of vegetation patterns and their dynamics ( 14 – 23 ).…”

mentioning

confidence: 99%

Phenotypic plasticity: A missing element in the theory of vegetation pattern formation

Bennett,

Bera,

Ferré

et al. 2023

Proc. Natl. Acad. Sci. U.S.A.

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Regular spatial patterns of vegetation are a common sight in drylands. Their formation is a population-level response to water stress that increases water availability for the few via partial plant mortality. At the individual level, plants can also adapt to water stress by changing their phenotype. Phenotypic plasticity of individual plants and spatial patterning of plant populations have extensively been studied independently, but the likely interplay between the two robust mechanisms has remained unexplored. In this paper, we incorporate phenotypic plasticity into a multi-level theory of vegetation pattern formation and use a fascinating ecological phenomenon, the Namibian “fairy circles,” to demonstrate the need for such a theory. We show that phenotypic changes in the root structure of plants, coupled with pattern-forming feedback within soil layers, can resolve two puzzles that the current theory fails to explain: observations of multi-scale patterns and the absence of theoretically predicted large-scale stripe and spot patterns along the rainfall gradient. Importantly, we find that multi-level responses to stress unveil a wide variety of more effective stress-relaxation pathways, compared to single-level responses, implying a previously underestimated resilience of dryland ecosystems.

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Evidence for scale-dependent root-augmentation feedback and its role in halting the spread of a pantropical shrub into an endemic sedge

Cited by 4 publications

References 56 publications

Microbial Factors May Contribute to the Persistence of Australian Fairy Circles

Microbial Factors May Contribute to the Persistence of Australian Fairy Circles

Habitat isolation diminishes potential of self-organised pattern formation to promote local diversity in metacommunities

Phenotypic plasticity: A missing element in the theory of vegetation pattern formation

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