Soil pH influences patterns of plant community composition after restoration with native‐based seed mixes

Barlow, Kathryn M.; Mortensen, David A.; Drohan, Patrick J.

doi:10.1111/rec.13141

Cited by 16 publications

(7 citation statements)

References 59 publications

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“…As for legumes, their exposure to high soil N may disrupt their physiological processes due to suppression of rhizobia fixation or the nitrogenase activity, which may explain the decreased effect with the increase in N levels (Tian et al, 2020). In addition, a number of theories or hypotheses related to environmental conditions have been proposed to explain plant community dynamics in response to N enrichment, like soil acidification (Barlow et al, 2020;Horswill et al, 2008) and ionic toxicity induced by acidification (Bowman et al, 2008;Tian et al, 2016Tian et al, , 2020. However, in our study, we did not observe a significant pH decrease probably due to the soil buffering capacity (Figure S1c).…”

Section: The Potential Mechanisms Of Plant Community Changes In Respo...mentioning

confidence: 99%

Microbial mediators of plant community response to long‐term N and P fertilization: Evidence of a role of plant responsiveness to mycorrhizal fungi

Wang

Koziol

Foster

et al. 2022

Global Change Biology

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Climate changes and anthropogenic nutrient enrichment widely threaten plant diversity and ecosystem functions. Understanding the mechanisms governing plant species turnover across nutrient gradients is crucial to developing successful management and restoration strategies. We tested whether and how soil microbes, particularly arbuscular mycorrhizal fungi (AMF), could mediate plant community response to a 15 years long-term N (0, 4, 8, and 16 g N m −2 year −1 ) and P (0 and 8 g N m −2 year −1 ) enrichment in a grassland system. We found N and P enrichment resulted in plant community diversity decrease and composition change, in which perennial C 4 graminoids were dramatically reduced while annuals and perennial forbs increased. Metabarcoding analysis of soil fungal community showed that N and P changed fungal diversity and composition, of which only a cluster of AMF identified by the co-occurrence networks analysis was highly sensitive to P treatments and was negatively correlated with shifts in percentage cover of perennial C 4 graminoids. Moreover, by estimating the mycorrhizal responsiveness (MR) of 41 plant species in the field experiment from 264 independent tests, we found that the community weighted mean MR of the plant community was substantially reduced with nutrient enrichment and was positively correlated with C 4 graminoids percentage cover. Both analyses of covariance and structural equation modeling indicated that the shift in MR rather than AMF composition change was the primary predictor of the decline in perennial C 4 graminoids, suggesting that the energy cost invested by C 4 plants on those sensitive AMF might drive the inferior competitive abilities compared with other groups. Our results suggest that shifts in the competitive ability of mycorrhizal responsive plants can drive plant community change to anthropogenic eutrophication, suggesting a functional benefit of mycorrhizal mutualism in ecological restoration following climatic or anthropogenic degradation of soil communities.

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Section: The Potential Mechanisms Of Plant Community Changes In Respo...mentioning

confidence: 99%

Microbial mediators of plant community response to long‐term N and P fertilization: Evidence of a role of plant responsiveness to mycorrhizal fungi

Wang

Koziol

Foster

et al. 2022

Global Change Biology

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“…Furthermore, NMDS identified the soil pH as a key site factor, structuring plant communities across these sites. Soil pH is a critical determinant of plant nutrient availability and can exert a profound influence on plant community structure and composition, especially in the restoration of degraded lands [67]. Urban soils are highly heterogeneous and exhibit complex effects of prior management [68]; these, and other legacy effects of human activity, structure plant communities [69,70].…”

Section: Discussionmentioning

confidence: 99%

Twenty Years of Urban Reforestation: Overstory Development Structures Understory Plant Communities in Lexington, KY, USA

et al. 2023

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Urban forests provide critical ecosystem services in an increasingly urbanized global landscape. The reforestation of undeveloped parcels and serially mowed grasslands can increase urban forest cover, but plant community development in planted urban forests is poorly understood. We conducted a study to elucidate the roles of time since tree planting, invasive species abundance, and other abiotic and biotic site-level factors in structuring understory plant communities within a 20-year chronosequence of planted urban forests in Lexington, KY, USA. We assessed the percent of groundcover of all understory species in fixed-radius plots on the site. Understory herbaceous plant communities demonstrated shifts from graminoid dominance to forb dominance over time, and plant communities in successively younger sites were increasingly dissimilar from that of the 20-year-old site. Invasive plant species were abundant, representing 21% of total groundcover across all surveyed plots, and became increasingly prevalent over time. Understory plant diversity was negatively associated with invasive species abundance. Overall, site factors, including time since planting, forest canopy closure, density of tree and shrub reproduction, and soil pH, accounted for much of the variability among understory communities. Understory plant communities across the chronosequence of planted sites demonstrated apparent structural shifts with overstory canopy development, but the increasing prevalence of invasive species and their negative impacts to plant diversity warrant future management to ensure the continuation of the desired successional trajectories.

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“…This indicates that soil salinity, pH, and water content may be the priority factors impacting seedling density. As the two main ecological limiting factors in this arid desert forest ecosystem, the increase in soil salinity and drought stresses can reduce seedling survival and seed germination through a change in osmotic pressure and electrolyte balance [43][44][45]. In addition, with the increase in these factors, the resistance of seedlings to fungal infection would be decreased, resulting in seedling death and changing the distribution pattern of seedling density [3,8,43,44].…”

Section: The Influencing Mechanisms Of Soil Fungi On Seedling Densitymentioning

confidence: 99%

Relationship between Soil Fungi and Seedling Density in the Vicinity of Adult Conspecifics in an Arid Desert Forest

Long

Yang

Cao

et al. 2021

Forests

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Research Highlights: 1. Soil fungi have a higher influence on seedling density compared to soil environmental factors; 2. Host-specific pathogens and beneficial fungi affect seeding density via different influencing mechanisms. Background and Objectives: The growth and development of seedlings are the key processes that affect forest regeneration and maintain community dynamics. However, the influencing factors of seedling growth around their adult conspecifics are not clear in arid desert forests. Probing the intrinsic relations among soil fungi, soil environmental factors (pH, water content, salinity, and nutrition), and seedling density will improve our understanding of forest development and provide a theoretical basis for forest management and protection. Materials and Methods: Four experimental plot types, depending on the distance to adult conspecifics, were set in an arid desert forest. Soil environmental factors, the diversity and composition of the soil fungal community, and the seedlings’ density and height were measured in the four experimental plot types, and their mutual relations were analyzed. Results: Seedling density as well as the diversity and composition of the soil fungal community varied significantly among the four plot types (p < 0.05). Soil environmental factors, especially soil salinity, pH, and soil water content, had significant influences on the seedling density and diversity and composition of the soil fungal community. The contribution of soil fungi (72.61%) to the variation in seedling density was much higher than the soil environmental factors (27.39%). The contribution of detrimental fungi to the variation in seedling density was higher than the beneficial fungi. Conclusions: Soil fungi mostly affected the distribution of seedling density in the vicinity of adult conspecifics in an arid desert forest. The distribution of seedling density in the vicinity of adults was mainly influenced by the detrimental fungi, while the adults in the periphery area was mainly influenced by the beneficial fungi.

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Soil pH influences patterns of plant community composition after restoration with native‐based seed mixes

Cited by 16 publications

References 59 publications

Microbial mediators of plant community response to long‐term N and P fertilization: Evidence of a role of plant responsiveness to mycorrhizal fungi

Microbial mediators of plant community response to long‐term N and P fertilization: Evidence of a role of plant responsiveness to mycorrhizal fungi

Twenty Years of Urban Reforestation: Overstory Development Structures Understory Plant Communities in Lexington, KY, USA

Relationship between Soil Fungi and Seedling Density in the Vicinity of Adult Conspecifics in an Arid Desert Forest

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