Intraspecific functional trait structure of restoration‐relevant species: Implications for restoration seed sourcing

Zeldin, Jacob; Lichtenberger, Taran M.; Foxx, Alicia J.; Williams, Evelyn W.; Kramer, Andrea T.

doi:10.1111/1365-2664.13603

Cited by 13 publications

(13 citation statements)

References 75 publications

(108 reference statements)

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“…Seeding also allows for the inclusion of higher numbers of species and genotypes relative to the more logistically intensive planting process (Godefroid et al, 2011;Reynolds et al, 2012). Higher genetic diversity is critical for the ability of plants to evolve in response to future changes, and both genetic and species diversity are essential to support ecosystem multifunctionality (section "Seed Source Diversity"), i.e., the simultaneous support of multiple ecosystem functions (Bischoff et al, 2010;Reynolds et al, 2012;Kettenring et al, 2014;Palma and Laurance, 2015;Espeland et al, 2017;Zeldin et al, 2020).…”

Section: Ecological Genetic and Evolutionary Benefits Of Seedingmentioning

confidence: 99%

“…Populations sampled should span a range of local to non-local sources across a region for a "regional admixture provenancing" approach (sensu Bucharova et al, 2019) unless there is strong evidence for outbreeding potential and maladaptation to drive a more conservative local-sourcing approach. On the contrary, many wetlands are in highly altered landscapes with substantial fragmentation, where the available seed may be of poor quality due to inbreeding or genetic drift in remaining remnant wetlands (Broadhurst et al, 2008;Borders et al, 2011;Jordan et al, 2019); thus regional admixture provenancing to increase genetic diversity and phenotypic plasticity in seed mixes would be appropriate especially as a "biological insurance" to extreme and fluctuating environments and to foster adaptive potential in the face of climate change (Hughes and Stachowicz, 2004;Reusch et al, 2005;Broadhurst et al, 2016;Zeldin et al, 2020). These recommendations for regional admixture provenancing are also consistent with the broad dispersal (section "Site and Landscape Context") and gene flow patterns of many avian-dispersed wetland species (Orsenigo et al, 2017;Kettenring et al, 2019b).…”

Section: Number and Choice Of Populationsmentioning

confidence: 99%

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Need to Seed? Ecological, Genetic, and Evolutionary Keys to Seed-Based Wetland Restoration

Kettenring

Tarsa

2020

Front. Environ. Sci.

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As we approach the Decade of Ecosystem Restoration (2021-2030), there is renewed focus on improving wetland restoration practices to reestablish the habitat and climate mitigation functions and services that wetlands provide. A first step in restoring these functions and services is to reestablish the native vegetation structure and composition through strategic seed-based approaches. These approaches should be driven by ecological, genetic, and evolutionary principles, along with consideration for economics, logistics, and other social constraints. Effective seed-based approaches must consider the chosen species, seed sourcing, dormancy break and germination requirements, seed enhancement technologies, potential invaders, seeding densities, and long-term monitoring. Choice of species should reflect historical plant communities and future environmental conditions, species that support functional goals including invasion resistance, and seed availability constraints. Furthermore, seeds should be sourced to ensure ample genetic diversity to support multifunctionality and evolutionary capacity while also considering the broad natural dispersal of many wetland species. The decision to collect wild seeds or purchase seeds will also impact species choice and genetic diversity, which can have cascading effects for functional goals. To ensure seedling establishment, seed dormancy should be addressed through dormancy breaking treatments and the potentially narrow germination requirements of some species will require targeted sowing timing and location to align with safe sites. Other seed enhancements such as priming and coatings are poorly developed for wetland restoration and their potential for improving establishment is unknown. Because wetlands are highly invasion prone, potential invaders and their legacies should be addressed. Seeding densities should strike a balance between outcompeting invaders and preserving valuable seed resources. Invader control and long-term monitoring is key to improving revegetation and restoration. Here, we review scientific advances to improve revegetation outcomes, and provide methods and recommendations to help achieve the desired goals. Gaps in knowledge about seed-based wetland restoration currently exist, however, and untested practices will certainly increase risks in future efforts. These efforts can be used to better understand the ecological, genetic, and evolutionary processes related to wetland seeds, which will bring us one step closer to seed-based restoration of functions and services needed for human and ecological communities.

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Section: Ecological Genetic and Evolutionary Benefits Of Seedingmentioning

confidence: 99%

Section: Number and Choice Of Populationsmentioning

confidence: 99%

Need to Seed? Ecological, Genetic, and Evolutionary Keys to Seed-Based Wetland Restoration

Kettenring

Tarsa

2020

Front. Environ. Sci.

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“…Moreover, weeds were mostly controlled manually rather than chemically as is typical, with the exception of an annual, early‐spring spot‐treatment of emerging Cirsium . Finally, we had one source of seeds and plant material per species and thus little intraspecific diversity and associated potential benefits for restoration outcomes and climate resilience (Khalil et al 2019; Zeldin et al 2020). We did not design our experiment to evaluate the importance to restoration of mixing populations for climate resilience or other factors (e.g.…”

Section: Discussionmentioning

confidence: 99%

Phylogenetically and functionally diverse species mixes beget diverse experimental prairies, whether from seeds or plugs

Barak

Karimi

Glasenhardt

et al. 2022

Restoration Ecology

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Phylogenetic and functional diversity are relevant for restoration planning, as they influence important ecosystem functions and services. However, it is unknown whether initial phylogenetic and functional diversity of restorations as planned and planted are maintained over time, that is, the extent to which diversity of the restoration planting is reflected in the diversity of the resulting plant community. Furthermore, in the tallgrass prairie, many restorations are planted from seed. Among-species variation in emergence and establishment affects the transition from seed mixes to realized plant communities in these restorations. We evaluated emergence and early establishment of experimental communities in a biodiversity plot experiment designed to test how phylogenetic and functional diversity influence restoration outcomes. We planted the same experimental communities starting from both seeds and plugs to assess differences in establishment. Our results suggest that phylogenetically and functionally diverse species mixes tend to produce phylogenetically and functionally diverse restored plant communities. After 3 years, experimental communities generally maintained their phylogenetic and functional diversity from seed and plug mixes to established vegetation, despite declines in species richness. While plots planted from seeds had on average 1.3 fewer species than plots planted from plugs, phylogenetic and functional diversity did not significantly differ between the two. Furthermore, most species exhibited no significant differences in percent cover when planted from seeds or plugs. Seeds are generally more cost-effective for restoration than plugs, and our results indicate these two establishment methods achieved similar biodiversity outcomes.

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“…Whitham [ 3 ] lamented the lack of good plant-material options for populations compromised at the warm end of species’ distributions. Furthermore, seed-transfer options may be limited due to the emergence of no-analog ecosystems as a response to climate change [ 139 , 140 , 141 , 142 ]. A justification for developing more effective native plant materials can be made on this basis.…”

Section: Discussionmentioning

confidence: 99%

Using Genomic Selection to Develop Performance-Based Restoration Plant Materials

Jones

Monaco

Larson

et al. 2022

IJMS

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Effective native plant materials are critical to restoring the structure and function of extensively modified ecosystems, such as the sagebrush steppe of North America’s Intermountain West. The reestablishment of native bunchgrasses, e.g., bluebunch wheatgrass (Pseudoroegneria spicata [Pursh] À. Löve), is the first step for recovery from invasive species and frequent wildfire and towards greater ecosystem resiliency. Effective native plant material exhibits functional traits that confer ecological fitness, phenotypic plasticity that enables adaptation to the local environment, and genetic variation that facilitates rapid evolution to local conditions, i.e., local adaptation. Here we illustrate a multi-disciplinary approach based on genomic selection to develop plant materials that address environmental issues that constrain local populations in altered ecosystems. Based on DNA sequence, genomic selection allows rapid screening of large numbers of seedlings, even for traits expressed only in more mature plants. Plants are genotyped and phenotyped in a training population to develop a genome model for the desired phenotype. Populations with modified phenotypes can be used to identify plant syndromes and test basic hypotheses regarding relationships of traits to adaptation and to one another. The effectiveness of genomic selection in crop and livestock breeding suggests this approach has tremendous potential for improving restoration outcomes for species such as bluebunch wheatgrass.

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Intraspecific functional trait structure of restoration‐relevant species: Implications for restoration seed sourcing

Cited by 13 publications

References 75 publications

Need to Seed? Ecological, Genetic, and Evolutionary Keys to Seed-Based Wetland Restoration

Need to Seed? Ecological, Genetic, and Evolutionary Keys to Seed-Based Wetland Restoration

Phylogenetically and functionally diverse species mixes beget diverse experimental prairies, whether from seeds or plugs

Using Genomic Selection to Develop Performance-Based Restoration Plant Materials

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