87 research outputs found
The Identification, Distribution, Impacts, Biology and Management of Noxious Rangeland Weeds
This document provides a discussion of the biology and management of exotic rangeland weeds which are a threat to native ecosystems of the western United States. Chapter 1 describes a generalized approach for managing noxious weed infested rangeland, while Chapter 2 focuses on preventing noxious weed invasion. In some cases, noxious weeds readily invade riparian areas, and because of the sensitive nature of these ecosystems Chapter 3 is devoted to riparian weed management. The following 13 chapters describe the identification, origin, history, distribution, potential invasion, impacts, biology and ecology, and management of specific noxious rangeland weeds
A New Perspective on Trait Differences Between Native and Invasive Exotic Plants
Functional differences between native and exotic species potentially constitute one factor responsible for plant invasion. Differences in trait values between native and exotic invasive species, however, should not be considered fixed and may depend on the context of the comparison. Furthermore, the magnitude of difference between native and exotic species necessary to trigger invasion is unknown. We propose a criterion that differences in trait values between a native and exotic invasive species must be greater than differences between co-occurring natives for this difference to be ecologically meaningful and a contributing factor to plant invasion. We used a meta-analysis to quantify the difference between native and exotic invasive species for various traits examined in previous studies and compared this value to differences among native species reported in the same studies. The effect size between native and exotic invasive species was similar to the effect size between co-occurring natives except for studies conducted in the field; in most instances, our criterion was not met although overall differences between native and exotic invasive species were slightly larger than differences between natives. Consequently, trait differences may be important in certain contexts, but other mechanisms of invasion are likely more important in most cases. We suggest that using trait values as predictors of invasion will be challenging
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Role of propagule pressure and priority effects on seedlings during invasion and restoration of shrub-steppe
Plant invasion and restoration outcomes
are largely driven by the timing and magnitude of seed
dispersal, and by the performance of dispersed species
in an environment. Because seed dispersal controls
recruitment of newly arriving species and facilitates
safe site occupation, assembly will differ depending
on seed dispersal processes and variable environmental
conditions. The objective of this study was to
identify how annual and perennial grasses assembled
when dispersal times, propagule pressure, and water
availability were modified. To assess these effects, we
conducted a field experiment in an annual grass
invaded shrub-steppe ecosystem in eastern Oregon.
We tested the effects of seeding annual and perennial
grasses in autumn or delaying annual grass seeding
until spring, adding water, and varying annual and
perennial grass seeding rate by 150, 1,500, 2,500, or
3,500 seeds m⁻² on perennial and annual grass
seedling emergence through time and final density
and biomass. Providing perennial grasses a priority
effect by delaying annual grass seeding until spring
initially facilitated perennial grass establishment, but
this effect did not persist into the second growing
season. We found that if annual grass propagule
pressure exceeded 150 seeds m⁻², perennial grass
recruitment was limited. In addition, higher water
availability increased perennial grass establishment,
but was dependent upon annual grass propagule
pressure. These findings suggest that seeding perennial
grasses into annual grass dominated systems is
more dependent upon the existing propagule pressure
of annual grasses than the priority effects of perennial
grasses, the propagule pressure of perennial grasses, or
water availability.Keywords: Invasion, Priority effects, Assembly, Water, Dispersal, Propagule pressureKeywords: Invasion, Priority effects, Assembly, Water, Dispersal, Propagule pressur
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Seed and seedling traits affecting critical life stage transitions and recruitment outcomes in dryland grasses
1. Seeding native plants is a key management practice to counter land degradation across
the globe, yet the majority of seeding efforts fail, limiting our ability to accelerate ecosystem
recovery.
2. Recruitment requires transitions through several seed and seedling stages, some of which
may have overriding influences on restoration outcomes. We lack, however, a general
framework to understand and predict differences in these critical demographic processes
across species. Functional traits influence fitness, and consequently, trait variation could provide
the basis for a framework to explain and predict variation in life stage transition probabilities.
3. We used seed and seedling traits, and field probabilities of germination, emergence, seedling
establishment, and survival for 47 varieties of drylands grasses under two watering treatments
to identify critical life stage transitions and quantify the effect of traits on cumulative
survival through the first growing season.
4. Variation in germination and emergence probabilities explained over 90% of the variation
in cumulative survival regardless of seedling survival probabilities or watering treatment, with
emergence probability being the strongest predictor of cumulative survival.
5. Coleoptile tissue density and seed mass had significant effects on emergence and germination,
respectively, explaining 10–23% of the variation in transition probabilities.
6. Synthesis and applications: While the majority of functional trait work has centred on linking
leaf and root traits to resource acquisition and utilization, our study demonstrates that
traits associated with germination and emergence may have prevailing influences on restoration
outcomes. A portion of these traits have been examined, but there is substantial opportunity
to identify other key traits driving these demographic processes. These advancements will
underpin our ability to develop trait-based frameworks for overcoming recruitment barriers
and facilitating recovery of degraded systems across the globe.Keywords: seeding, path analysis, seed mass, emergence, functional traits, coleoptile tissue density, germination, hydrothermal time, demograph
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Do key dimensions of seed and seedling functional trait variation capture variation in recruitment probability?
Seedling recruitment is a critical driver of population dynamics and community assembly, yet we know little about functional traits that define different recruitment strategies. For the first time, we examined whether trait relatedness across germination and seedling stages allows the identification of general recruitment strategies which share core functional attributes and also correspond to recruitment outcomes in applied settings. We measured six seed and eight seedling traits (lab- and field-collected, respectively) for 47 varieties of dryland grasses and used principal component analysis (PCA) and cluster analysis to identify major dimensions of trait variation and to isolate trait-based recruitment groups, respectively. PCA highlighted some links between seed and seedling traits, suggesting that relative growth rate and root elongation rate are simultaneously but independently associated with seed mass and initial root mass (first axis), and with leaf dry matter content, specific leaf area, coleoptile tissue density and germination rate (second axis). Third and fourth axes captured separate tradeoffs between hydrothermal time and base water potential for germination, and between specific root length and root mass ratio, respectively. Cluster analysis separated six recruitment types along dimensions of germination and growth rates, but classifications did not correspond to patterns of germination, emergence or recruitment in the field under either of two watering treatments. Thus, while we have begun to identify major threads of functional variation across seed and seedling stages, our understanding of how this variation influences demographic processes—particularly germination and emergence—remains a key gap in functional ecology.Keywords: Emergence, Survival, Plant functional type, Germination, Root
Invasive annual grasses—Reenvisioning approaches in a changing climate
For nearly a century, invasive annual grasses have increasingly impacted terrestrial ecosystems across the western United States. Weather variability associated with climate change and increased atmospheric carbon dioxide (CO2) are making even more difficult the challenges of managing invasive annual grasses. As part of a special issue on climate change impacts on soil and water conservation, the topic of invasive annual grasses is being addressed by scientists at the USDA Agricultural Research Service to emphasize the need for additional research and future studies that build on current knowledge and account for (extreme) changes in abiotic and biotic conditions. Much research has focused on understanding the mechanisms underlying annual grass invasion, as well as assessing patterns and responses from a wide range of disturbances and management approaches. Weather extremes and the increasing occurrences of wildfire are contributing to the complexity of the problem. In broad terms, invasive annual grass management, including restoration, must be proactive to consider human values and ecosystem resiliency. Models capable of synthesizing vast amounts of diverse information are necessary for creating trajectories that could result in the establishment of perennial systems. Organization and collaboration are needed across the research community and with land managers to strategically develop and implement practices that limit invasive annual grasses. In the future, research will need to address invasive annual grasses in an adaptive integrated weed management (AIWM) framework that utilizes models and accounts for climate change that is resulting in altered/new approaches to management and restoration
Agricultural Research Service Weed Science Research: Past, Present, and Future
The U.S. Department of Agriculture-Agricultural Research Service (USDA-ARS) has been a leader in weed science research covering topics ranging from the development and use of integrated weed management (IWM) tactics to basic mechanistic studies, including biotic resistance of desirable plant communities and herbicide resistance. ARS weed scientists have worked in agricultural and natural ecosystems, including agronomic and horticultural crops, pastures, forests, wild lands, aquatic habitats, wetlands, and riparian areas. Through strong partnerships with academia, state agencies, private industry, and numerous federal programs, ARS weed scientists have made contributions to discoveries in the newest fields of robotics and genetics, as well as the traditional and fundamental subjects of weed-crop competition and physiology and integration of weed control tactics and practices. Weed science at ARS is often overshadowed by other research topics; thus, few are aware of the long history of ARS weed science and its important contributions. This review is the result of a symposium held at the Weed Science Society of America\u27s 62nd Annual Meeting in 2022 that included 10 separate presentations in a virtual Weed Science Webinar Series. The overarching themes of management tactics (IWM, biological control, and automation), basic mechanisms (competition, invasive plant genetics, and herbicide resistance), and ecosystem impacts (invasive plant spread, climate change, conservation, and restoration) represent core ARS weed science research that is dynamic and efficacious and has been a significant component of the agency\u27s national and international efforts. This review highlights current studies and future directions that exemplify the science and collaborative relationships both within and outside ARS. Given the constraints of weeds and invasive plants on all aspects of food, feed, and fiber systems, there is an acknowledged need to face new challenges, including agriculture and natural resources sustainability, economic resilience and reliability, and societal health and well-being
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Western Land Managers will Need all Available Tools for Adapting to Climate Change, Including Grazing: A Critique of Beschta et al.
In a previous article, Beschta et al. (Environ
Manag 51(2):474–491, 2013) argue that grazing by large
ungulates (both native and domestic) should be eliminated
or greatly reduced on western public lands to reduce
potential climate change impacts. The authors did not
present a balanced synthesis of the scientific literature, and
their publication is more of an opinion article. Their conclusions
do not reflect the complexities associated with
herbivore grazing. Because grazing is a complex ecological process, synthesis of the scientific literature can be a
challenge. Legacy effects of uncontrolled grazing during
the homestead era further complicate analysis of current
grazing impacts. Interactions of climate change and grazing
will depend on the specific situation. For example,
increasing atmospheric CO₂ and temperatures may increase
accumulation of fine fuels (primarily grasses) and thus
increase wildfire risk. Prescribed grazing by livestock is
one of the few management tools available for reducing
fine fuel accumulation. While there are certainly points on
the landscape where herbivore impacts can be identified, there are also vast grazed areas where impacts are minimal.
Broad scale reduction of domestic and wild herbivores to
help native plant communities cope with climate change
will be unnecessary because over the past 20–50 years land
managers have actively sought to bring populations of
native and domestic herbivores in balance with the potential
of vegetation and soils. To cope with a changing climate,
land managers will need access to all available
vegetation management tools, including grazing.Keywords: Grazing, Riparian areas, Public lands, Climate chang
Review of \u3ci\u3e Alien Species in North America and Hawaii: Impacts on Natural Ecosystems\u3c/i\u3e by George W. Cox
This enthusiastic conservationist chronicles the arrival and expansion of many keystone non-indigenous species into North America and Hawaii. A wealth of knowledge is pulled together to provide an overview of the impacts of invasive plants and animals on regional ecosystems. Alien Species should be required reading for natural resource managers. The author provides regional, biotic, theoretical, and policy perspectives on invasive species and discusses key invasive plants and animals and their known impacts within ten regions. This is the most extensive and documented part of the volume and provides powerful testimony regarding the magnitude of the problem
Step-by-Step Strategies for Restoring Western Rangelands
Invasive plants exploit every environmental angle in their favor. So restoring damaged rangelands in the western United States involves a lot more than just getting rid of bad plants and bringing in good plants.
Since 1990, Agricultural Research Service ecologist Roger Sheley has been refining a process for identifying factors that give the undesirable space invaders their territorial edge—and figuring out strategies for restoring a healthy mix of native vegetation for rangelands in need of remediation.
“Killing a weed is like treating a symptom,” says Sheley, who is co-located at Oregon State University’s Eastern Oregon Agricultural Research Center in Burns, Oregon. “So our research has been focused on trying to understand the reason why plants are able to invade and dominate some landscapes and not able to succeed in others. We want to find the cause and then deal with the cause—what has changed in the ecology of the system and how can we change it back?”
Sheley used a range of findings in the literature and years of field research at Burns to develop a decision-making model called “Ecologically Based Invasive-Plant Management” (EBIPM). The process is a mix of longstanding theories of plant establishment and succession, new ecological principles, identification of variables that contribute to invasive plant management, and actions that can help native plants regain territory lost to invasive vegetation
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