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2. Rapid upwards spread of non-native plants in mountains across continents

Author

Iseli, Evelin, Chisholm, Chelsea, Lenoir, Jonathan, Haider, Sylvia, Seipel, Tim, Barros, Agustina, Hargreaves, Anna L., Kardol, Paul, Lembrechts, Jonas J., McDougall, Keith, Rashid, Irfan, Rumpf, Sabine B., Arévalo, José Ramón, Cavieres, Lohengrin, Daehler, Curtis, Dar, Pervaiz A., Endress, Bryan, Jakobs, Gabi, Jiménez, Alejandra, Küffer, Christoph, Mihoc, Maritza, Milbau, Ann, Morgan, John W., Naylor, Bridgett J., Pauchard, Aníbal, Ratier Backes, Amanda, Reshi, Zafar A., Rew, Lisa J., Righetti, Damiano, Shannon, James M., Valencia, Graciela, Walsh, Neville, Wright, Genevieve T., and Alexander, Jake M.

Published
2023
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3. Roadside disturbance promotes plant communities with arbuscular mycorrhizal associations in mountain regions worldwide.

Author

Clavel, Jan, Lembrechts, Jonas J., Lenoir, Jonathan, Haider, Sylvia, McDougall, Keith, Nuñez, Martin A., Alexander, Jake, Barros, Agustina, Milbau, Ann, Seipel, Tim, Pauchard, Anibal, Fuentes‐Lillo, Eduardo, Ratier Backes, Amanda, Dar, Pervaiz, Reshi, Zafar A., Aleksanyan, Alla, Zong, Shengwei, Arevalo Sierra, José Ramón, Aschero, Valeria, and Verbruggen, Erik

Subjects
MOUNTAIN ecology, ECOLOGICAL disturbances, ROADSIDE improvement, ANTHROPOGENIC effects on nature, GROUND cover plants, ECOSYSTEMS, PLANT communities
Abstract

We assessed the impact of road disturbances on the dominant mycorrhizal types in ecosystems at the global level and how this mechanism can potentially lead to lasting plant community changes. We used a database of coordinated plant community surveys following mountain roads from 894 plots in 11 mountain regions across the globe in combination with an existing database of mycorrhizal–plant associations in order to approximate the relative abundance of mycorrhizal types in natural and disturbed environments. Our findings show that roadside disturbance promotes the cover of plants associated with arbuscular mycorrhizal (AM) fungi. This effect is especially strong in colder mountain environments and in mountain regions where plant communities are dominated by ectomycorrhizal (EcM) or ericoid‐mycorrhizal (ErM) associations. Furthermore, non‐native plant species, which we confirmed to be mostly AM plants, are more successful in environments dominated by AM associations. These biogeographical patterns suggest that changes in mycorrhizal types could be a crucial factor in the worldwide impact of anthropogenic disturbances on mountain ecosystems. Indeed, roadsides foster AM‐dominated systems, where AM‐fungi might aid AM‐associated plant species while potentially reducing the biotic resistance against invasive non‐native species, often also associated with AM networks. Restoration efforts in mountain ecosystems will have to contend with changes in the fundamental make‐up of EcM‐ and ErM plant communities induced by roadside disturbance. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Ain't No Mountain High Enough: Plant Invasions Reaching New Elevations

Author

Pauchard, Aníbal, Kueffer, Christoph, Dietz, Hansjörg, Daehler, Curtis C., Alexander, Jake, Edwards, Peter J., Arévalo, José Ramón, Cavieres, Lohengrin A., Guisan, Antoine, Haider, Sylvia, Jakobs, Gabi, McDougall, Keith, Millar, Constance I., Naylor, Bridgett J., Parks, Catherine G., Rew, Lisa J., and Seipel, Tim

Published
2009
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15. Cropping systems alter plant volatile emissions in the field through soil legacy effects.

Author

Malone, Shealyn C., Menalled, Fabian D., Weaver, David K., Seipel, Tim F., Hofland, Megan L., Runyon, Justin B., Bourgault, Maryse, Boss, Darrin L., and Trowbridge, Amy M.

Subjects
CROP rotation, CROPPING systems, ARID regions agriculture, COVER crops, PEST control, CROPS, SOIL moisture, SOIL air, WATER requirements for crops
Abstract

Crops emit a variety of volatile organic compounds (VOCs) that serve as attractants or repellents for pests and their natural enemies. Crop rotations, off-farm chemical inputs, and mechanical and cultural tactics – collectively called cropping systems – alter soil nutrients, moisture content, and microbial communities, all of which have the potential to alter crop VOC emissions. Soil legacy effects of diversified cropping systems have been shown to enhance crop VOC emissions in greenhouse studies, but how they influence emissions under field conditions remains virtually unknown. To determine the effect of cropping systems on plant VOC emissions in the field, air samples were collected from the headspace of wheat (Triticum aestivum L. Judee) grown in simplified wheat-fallow rotations or diversified wheat-cover crop rotations where cover crops were terminated by grazing cattle. Across two growing seasons, wheat grown in rotation with fallow emitted greater amounts of Z -3-hexenyl acetate and β-ocimene, key attractants for wheat stem sawfly (Cephus cinctus Norton), a major pest of wheat. While overall VOC blends were relatively similar among cropping system during the first growing season, emissions varied substantially in the second year of this study where wheat grown in rotation with cover crops emitted substantially greater quantities of volatile compounds characteristic of abiotic stress. Below-average precipitation in the second growing season, in addition to reduced soil water content in cover crop rotations, suggests that cropping system effects on wheat VOCs may have been driven primarily by water availability, a major factor limiting crop growth in dryland agriculture. While the specific mechanisms driving changes in VOC emissions were not explicitly tested, this work shows that agricultural practices applied in one growing season can differentially influence crop VOC emissions in the next through soil legacy effects, illustrating additional avenues through which cropping systems may be leveraged to enhance pest management. [ABSTRACT FROM AUTHOR]

Published
2022
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17. Weed Communities in Winter Wheat: Responses to Cropping Systems under Different Climatic Conditions.

Author

Seipel, Tim, Ishaq, Suzanne L., Larson, Christian, and Menalled, Fabian D.

Abstract

Understanding the impact of biological and environmental stressors on cropping systems is essential to secure the long-term sustainability of agricultural production in the face of unprecedented climatic conditions. This study evaluated the effect of increased soil temperature and reduced moisture across three contrasting cropping systems: a no-till chemically managed system, a tilled organic system, and an organic system that used grazing to reduce tillage intensity. Results showed that while cropping system characteristics represent a major driver in structuring weed communities, the short-term impact of changes in temperature and moisture conditions appear to be more subtle. Weed community responses to temperature and moisture manipulations differed across variables: while biomass, species richness, and Simpson's diversity estimates were not affected by temperature and moisture conditions, we observed a minor but significant shift in weed community composition. Higher weed biomass was recorded in the grazed/reduced-till organic system compared with the tilled-organic and no-till chemically managed systems. Weed communities in the two organic systems were more diverse than in the no-till conventional system, but an increased abundance in perennial species such as Cirsium arvense and Taraxacum officinale in the grazed/reduced-till organic system could hinder the adoption of integrated crop-livestock production tactics. Species composition of the no-till conventional weed communities showed low species richness and diversity, and was encompassed in the grazed/reduced-till organic communities. The weed communities of the no-till conventional and grazed/reduced-till organic systems were distinct from the tilled organic community, underscoring the effect that tillage has on the assembly of weed communities. Results highlight the importance of understanding the ecological mechanisms structuring weed communities, and integrating multiple tactics to reduce off-farm inputs while managing weeds. [ABSTRACT FROM AUTHOR]

Published
2022
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18. Predicted climate conditions and cover crop composition modify weed communities in semiarid agroecosystems.

Author

DuPre, Mary E., Seipel, Tim, Bourgault, Maryse, Boss, Darin L., and Menalled, Fabian D.

Subjects
*WEED competition, *COVER crops, *AGRICULTURAL ecology, *ENERGY crops, *WEEDS, *WEED control, *ARID regions agriculture, *SPECIES diversity
Abstract

The US Northern Great Plains is one of the largest expanses of small grain agriculture, but excessive reliance on off‐farms inputs and predicted warmer and drier conditions hinder its agricultural sustainability. In this region, the use of cover crops represents a promising approach to increase biodiversity and reduce external inputs; however little information exists about how cover crop mixture composition, predicted climate and management systems could impact the performance of cover crops and weed communities. In the 4th cycle of a cover crop‐wheat rotation, we experimentally increased temperature and reduced moisture as expected to occur with climate change, and assessed impacts on the presence and composition of cover crop mixtures and termination methods on weed communities. Under ambient climate conditions, mean total cover crop biomass was 43%–53% greater in a five species early‐season cover crop mixture compared with a seven species mid‐season mixture, and differences were less pronounced in warmer and drier conditions (19%–24%). We observed a total of 18 weed species; 13 occurring in the early‐season mixture, 13 in the mid‐season mixtures and 14 in the fallow treatments. Weed species richness and diversity was lower in warmer and drier treatments, and we observed a shift in weed communities due to the presence and composition of cover crop mixtures as well as climate manipulations. Overall, results suggest that adoption of cover crop mixtures in semiarid agroecosystems requires jointly addressing weed management and soil moisture retention goals, a challenge further complicated by predicted climate conditions. [ABSTRACT FROM AUTHOR]

Published
2022
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19. Plant community responses to integrating livestock into a reduced‐till organic cropping system.

Author

Larson, Christian D., Menalled, Fabian D., Lehnhoff, Erik A., and Seipel, Tim

Subjects
CROPPING systems, PLANT diversity, PLANT communities, AGROBIODIVERSITY, WEED control, ORGANIC farming, NO-tillage
Abstract

The problems with herbicide‐ and tillage‐based weed management in agriculture are well documented and have precipitated research into finding alternatives. Integrating livestock grazing into organic agroecosystems has benefits and is a viable method for terminating cover crops, yet its impacts on weed communities are largely unknown. This lack of knowledge is particularly true in semi‐arid environments, including the Northern Great Plains, where we conducted our research. We compared weed community responses (biomass, species richness, Simpson's diversity, composition) of a sheep‐grazed organic cropping system with those of two contrasting cropping systems (high input conventional no‐till, tilled organic) across a five‐year crop rotation (safflower, sweet clover, winter wheat, lentils, winter wheat). We found that the conventional no‐till and tilled organic systems suppressed weed biomass and reduced species richness and diversity, while the grazed organic resulted in higher weed biomass, species richness, and diversity. During the first two years of the study, the composition of the two organic communities were distinct from the conventional no‐till communities but were indistinguishable from one another. Over the final three years of the study, grazed organic communities were tightly grouped and became distinct from both the tilled and conventional communities. We found that weed biomass and diversity were highest in the sweet clover and lowest in the winter wheat. The spring annual crops, safflower and lentil, demonstrated similar weed biomass, species richness, and composition. Our findings indicate that integrating livestock into cropping systems alters plant communities and increases the agroecosystem plant biodiversity of semi‐arid organic farming and that specific crops interact with cropping systems to alter agroecosystem plant communities. However, the increase in weed biomass associated with our grazing treatment makes this approach impractical as the sole weed management strategy and necessitates that integrating livestock into semi‐arid organic cropping systems must be part of a larger integrated weed management program. [ABSTRACT FROM AUTHOR]

Published
2021
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20. Farming system effects on biologically mediated plant–soil feedbacks.

Author

Menalled, Uriel D., Seipel, Tim, and Menalled, Fabian D.

Subjects
SUSTAINABLE agriculture, FARM management, CROP rotation, CROPPING systems, WEED competition, NO-tillage, WEEDS
Abstract

Cropping system characteristics such as tillage intensity, crop identity, crop-livestock integration and the application of off-farm synthetic inputs influence weed abundance, plant community composition and crop-weed competition. The resulting plant community, in turn, has species-specific effects on soil microbial communities which can impact the growth and competitive ability of subsequent plants, completing a plant–soil feedback (PSF) loop. Farming systems that minimize the negative impacts of PSFs on subsequent crop growth can increase the sustainability of the farming enterprise. This study sought to assess the individual and combined impact of the cropping system (certified organic-grazed, certified organic till and conventional no-till) and crop sequence [pairwise rotations with safflower (Carthamus tinctorius), yellow sweet clover (Melilotus officinalis) and winter wheat (Triticum aestivum)] on the PSF magnitude and direction. All cropping systems followed the same 5-year rotation and had completed one full rotation before soil was sampled. In a greenhouse setting, a sterile soil mix was inoculated with field soil collected from all systems and three crops. The PSF study consisted of two stages (conditioning and response phases) that mimicked the rotation stages occurring in the field. PSFs were calculated by comparing the biomass of the response phase plants grown in inoculated and uninoculated soils. The farm management system affected PSFs, inferring that tillage reduction can encourage more positive PSFs. Crop sequence did not affect PSF but interacted strongly with the farm system. As such, the effects of the farming system on PSFs are best illustrated when taken into account with the identity of the previous and current crops of a cropping sequence. [ABSTRACT FROM AUTHOR]

Published
2021
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22. Agroecosystem resilience is modified by management system via plant–soil feedbacks.

Author

Seipel, Tim, Ishaq, Suzanne L., and Menalled, Fabian D.

Subjects
PEAS, FARM management, AGRICULTURAL productivity, WHEAT, WINTER wheat, CROPPING systems, INCEPTISOLS
Abstract

Designing resilient cropping systems is essential to sustain agricultural production in the face of changing environmental and social pressures. However, the extent to which changes in farm management systems could alter resistance and resilience is largely unknown, especially in response to climate change. Plant and soil microbial community interactions are a vital component of functioning and resilient agroecosystems. The aim of our study was to use winter wheat (Triticum aestivum L.) and pea (Pisum sativum L.) plant–soil feedbacks (i.e. plant species-specific effects on soil biota and their impacts on subsequent plant growth) as a metric of system resilience and resistance to climate variability in three different farming management systems: 1) a chemical no-till system, 2) an USDA-certified organic system reliant on tillage and 3) an USDA-certified organic system that included sheep grazing with the overall goal of minimizing tillage intensity. Climate conditions soil experienced were ambient, warmer, and warmer and drier and were manipulated in the field using open-top chamber and rain-out shelters. Plant–soil feedbacks were negative for wheat and positive for pea but varied among farming management systems but were less sensitive to climate conditions. Plant–soil feedbacks were lower in magnitude in the tilled organic system indicating more resistance to the accumulation of pathogenic soil microbiota resulting from repeated cropping of wheat. However, recovery was lower when the crop was pea in the tilled organic indicating slower recovery and less resilience. Results indicate that while increases in crop diversity may promote more resilient agroecosystems, farming management will affect agroecosystem resilience. [ABSTRACT FROM AUTHOR]

Published
2019
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23. Farming system and wheat cultivar affect infestation of, and parasitism on, Cephus cinctus in the Northern Great Plains.

Author

Adhikari, Subodh, Seipel, Tim, Menalled, Fabian D, and Weaver, David K

Subjects
CEPHUS cinctus, HYMENOPTERA, CEPHIDAE, PARASITOIDS, WINTER wheat
Abstract

BACKGROUND: Cephus cinctus infestation causes $350 million in annual losses in the Northern Great Plains. We compared infestation and parasitism of C. cinctus in spring (including Kamut; Triticum turgidum ssp. turanicum) and winter wheat cultivars grown in organic and conventional fields in Montana, USA. In the greenhouse, we compared C. cinctus preference and survival in Kamut, Gunnison, and Reeder spring wheat cultivars. RESULTS: Stems cut by C. cinctus varied by farming system and the seasonality of the wheat crop. No stems of Kamut in organic fields were cut by C. cinctus, but 1.5% [±0.35% standard error (SE)] of stems in conventional spring wheat, 5% (±0.70% SE) of stems in organic winter wheat, and 20% (±0.93% SE) of stems in conventional winter wheat fields were cut by C. cinctus. More larvae of C. cinctus were parasitized in organic (27 ± 0.03% SE) compared with conventional (5 ± 0.01% SE) winter wheat fields. Cephus cinctus oviposition, survival, and the number of stems cut were lowest in Kamut compared with Gunnison and Reeder. CONCLUSION: Cephus cinctus infestation was more common in winter wheat than in spring wheat. Organic fields with fewer cut stems also supported more parasitoids. Kamut is a genetic resource for developing C. cinctus‐resistant cultivars. © 2018 Society of Chemical Industry Cephuscinctusis a major pest of grain crops. We found a greater infestation of C. cinctusin winter wheat and a lower preference to Kamut wheat. [ABSTRACT FROM AUTHOR]

Published
2018
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24. Temperature and Alternative Hosts Influence Aceria tosichella Infestation and Wheat Streak Mosaic Virus Infection.

Author

Ranabhat, Nar B., Seipel, Tim, Lehnhoff, Erik A., Miller, Zach J., Owen, Karl E., Burrows, Mary E., and Menalled, Fabian D.

Subjects
*ACERIA tosichella, *WHEAT streak mosaic virus, *WHEAT diseases & pests, *TICK infestations, *MITE hosts, *TEMPERATURE effect
Abstract

Wheat streak mosaic, caused by Wheat streak mosaic virus (WSMV; family Potyviriclae), is the most important and common viral disease of wheat (Triticum aestivum L.) in the Great Plains of North America. WSMV is transmitted by the wheat curl mite (WCM; Aceria tosichella). We evaluated how mean daily temperatures, cumulative growing degree-days, day of the year, and sumounding alternative host identity affected WCM infestation and WSMV infection of wheat from late summer through early autumn in Montana, United States. Cumulative growing degree-days, warm mean daily temperatures (i.e.. >10°C), and sumounding alternative hosts interacted to alter risk of WCM infestation and WSMV infection. Wheat sumounded by Bromus tectorum L. and preharvest volunteer wheat had WCM infestation and WSMV infection rates of 88% in years when the mean daily temperature was 15°C in October, compared with 23% when sumounded by bare ground, and <1% when the temperature was 0°C regardless of sumounding alternative host. Mean daily temperatures in the cereal-growing regions of Montana during autumn are marginally conducive to WCM population growth and movement. As the region continues to warm, the period of WCM movement will become longer, potentially increasing the frequency of WSMV outbreaks. [ABSTRACT FROM AUTHOR]

Published
2018
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25. Plant invasions into mountains and alpine ecosystems: current status and future challenges.

Author

Alexander, Jake, Lembrechts, Jonas, Cavieres, Lohengrin, Daehler, Curtis, Haider, Sylvia, Kueffer, Christoph, Liu, Gang, McDougall, Keith, Milbau, Ann, Pauchard, Aníbal, Rew, Lisa, and Seipel, Tim

Abstract

Recent years have seen a surge of interest in understanding patterns and processes of plant invasions into mountains. Here, we synthesise current knowledge about the spread of non-native plants along elevation gradients, emphasising the current status and impacts that these species have in alpine ecosystems. Globally, invasions along elevation gradients are influenced by propagule availability, environmental constraints on population growth, evolutionary change and biotic interactions. The highest elevations are so far relatively free from non-native plants. Nonetheless, in total nearly 200 non-native plant species have been recorded from alpine environments around the world. However, we identified only three species as specifically cold-adapted, with the overwhelming majority having their centres of distribution under warmer environments, and few have substantial impacts on native communities. A combination of low propagule availability and low invasibility likely explain why alpine environments host few non-native plants relative to lowland ecosystems. However, experiences in some areas demonstrate that alpine ecosystems are not inherently resistant to invasions. Furthermore, they will face increasing pressure from the introduction of pre-adapted species, climate change, and the range expansion of native species, which are already causing concern in some areas. Nonetheless, because they are still relatively free from non-native plants, preventative action could be an effective way to limit future impacts of invasions in alpine environments. [ABSTRACT FROM AUTHOR]

Published
2016
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26. Range limits and population dynamics of non-native plants spreading along elevation gradients.

Author

Seipel, Tim, Alexander, Jake M., Edwards, Peter J., and Kueffer, Christoph

Subjects
*POPULATION dynamics, *INTRODUCED plants, *PLANT invasions, *PLANT species, *BIODIVERSITY
Abstract

Monitoring the elevation limits of non-native species is a potentially sensitive means of detecting effects of environmental change on invasion dynamics and species ranges. The aim of this study was to investigate temporal changes in the distribution of non-native plant species along elevation gradients in the Swiss Alps by repeating, in 2009, a regional survey from 2003 of 230 sites ranging in elevation from 200 to 2400 m a.s.l. We also studied the fine-scale spatiotemporal population structure of two of the non-native species – Erigeron annuus and Solidago canadensis – along an elevation gradient in a heterogeneous landscape. Most non-native species in the Swiss Alps rapidly decline in probability of occurrence as elevation increases. We found little change in the elevation ranges limits of species in time, suggesting that most species are not rapidly expanding at their high elevation range limits. For most species, populations were more dynamic (colonizations and extinctions) at the upper range limit where occurrence rapidly declined. Population turnover was negatively correlated with probability of occurrence at the regional and local scale. At low elevations, where probability of occurrence was higher, the number of individuals in a population was also greater. At the local and regional scales, E. annuus and S. canadensis had similar range limits. At the local scale, propagule production of both E. annuus and S. canadensis was greater in the core of their distributions at lower elevations, and distance to nearest neighbor increased as occurrence decreased. Our data demonstrate that range limits of non-native species at high elevation are associated with high population turnover, which results in a transition zone characterized by source-sink dynamics. Populations within this zone exhibit reduced probability of occurrence, and smaller patches. This result has important implications for the monitoring of spreading species along environmental gradients. To understand these limits and predict range expansion, multi-year monitoring and demography data that includes information on colonization and extinction events will be needed. [ABSTRACT FROM AUTHOR]

Published
2016
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27. Fire and development influences on sagebrush community plant groups across a climate gradient in northern Nevada.

Author

Wood, David J. A., Seipel, Tim, Irvine, Kathryn M., Rew, Lisa J., and Stoy, Paul C.

Subjects
PLANT communities, SHRUBS, VEGETATION monitoring, LAND management, CHEATGRASS brome, SOCIAL influence, VEGETATION management
Abstract

The sagebrush biome covers much of the western United States yet is at risk from ongoing disturbances. Physical disturbances such as fire often overcome the resistance of sagebrush communities to biological disturbances such as invasion by non‐native species, but the impact of burn severity or combined disturbance types on sagebrush community composition remains unclear. We examined the relationship between native functional groups and non‐native annual grass cover to the number of fires, burn severity, anthropogenic development, and vegetation treatments in northern Nevada, USA. We used Bureau of Land Management vegetation monitoring plots and existing climate, fire, and vegetation treatment databases to explore relationships using beta regression. After accounting for mean annual precipitation and temperature, and elevation, we quantified functional group mean cover related to levels of burn severity, numbers of fires, development, and vegetation treatments. Native herbaceous (grass and forb) groups were resilient to fire, but fire caused large declines in shrub and sagebrush cover. Non‐native annual grass cover was associated with higher burn severity and the first fire at a site. We did not find evidence that post‐fire restoration treatments were associated with increased native cover or decreased non‐native cover. However, shrub control and soil disturbing treatments (discing and chaining) were associated with decreased native perennial grass cover and increased non‐native annual grass cover. Functional groups displayed varying patterns related to anthropogenic development and fire. For example, development had a larger impact on non‐native cover at lower levels of burn severity, whereas forbs increased following fire only at lower levels of development. Although in some cases sagebrush communities showed resilience to disturbance, our results showed resistance to invasion by non‐native annual grasses can be overcome by combinations of disturbances at lower levels or by severe events. [ABSTRACT FROM AUTHOR]

Published
2019
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28. Integrated Management of Cheatgrass (Bromus tectorum) with Sheep Grazing and Herbicide.

Author

Lehnhoff, Erik A., Rew, Lisa J., Mangold, Jane M., Seipel, Tim, and Ragen, Devon

Subjects
HERBICIDES, GRAZING, CHEATGRASS brome, HERBICIDE application, RANGELANDS, SHEEP
Abstract

Cheatgrass (Bromus tectorum L.) is one of the most problematic weeds in western United States rangelands and sagebrush steppe. It responds positively to different forms of disturbance, and its management has proven difficult. Herbicide or targeted grazing alone often fail to provide adequate long-term control. Integrating both may afford better control by providing multiple stressors to the weed. We assessed herbicide application, targeted sheep grazing and integrated herbicide and grazing on B. tectorum and the plant community in rangeland in southwestern Montana from 2015 until 2017. Herbicide treatments included spring-applied (May 2015 and 2016) glyphosate, fall-applied (October 2015) glyphosate, imazapic and rimsulfuron, and spring-applied glyphosate plus fall-applied imazapic. Targeted grazing, consisting of four sheep/0.01 ha for a day in 5 m × 20 m plots (all vegetation removed to the ground surface), occurred twice (May 2015 and 2016). While no treatments reduced B. tectorum biomass or seed production, grazing integrated with fall-applied imazapic or rimsulfuron reduced B. tectorum cover from approximately 26% to 14% in 2016 and from 33% to 16% in 2017, compared to ungrazed control plots, and by an even greater amount compared to these herbicides applied without grazing. By 2017, all treatments except spring-applied glyphosate increased total plant cover (excluding B. tectorum) by 8%–12% compared to the control plots, and forbs were generally responsible for this increase. Bromus tectorum management is difficult and our results point to a potential management paradox: Integrating grazing and fall-applied herbicide decreased B. tectorum cover but did not increase native grass cover, while some herbicides without grazing increased native grass cover, but failed to control B. tectorum. Additional research is necessary to determine grazing strategies that will complement herbicide control of B. tectorum while also stimulating native grass recovery, but this initial study demonstrates the potential of integrated management of B. tectorum compared to grazing or herbicide alone. [ABSTRACT FROM AUTHOR]

Published
2019
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