14 results on '"Alexander, Jake"'
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2. Different genetic clines in response to temperature across the native and introduced ranges of a global plant invader
- Author
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Alexander, Jake M., van Kleunen, Mark, Ghezzi, Reto, and Edwards, Peter J.
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- 2012
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3. Alien flora of mountains: global comparisons for the development of local preventive measures against plant invasions
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McDougall, Keith L., Alexander, Jake M., Haider, Sylvia, Pauchard, Aníbal, Walsh, Neville G., and Kueffer, Christoph
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- 2011
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4. Plant Invasions along Mountain Roads: The Altitudinal Amplitude of Alien Asteraceae Forbs in Their Native and Introduced Ranges
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Alexander, Jake M., Naylor, Bridgett, Poll, Myriam, Edwards, Peter J., and Dietz, Hansjörg
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- 2009
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5. Seedling Establishment of Asteraceae Forbs along Altitudinal Gradients: A Comparison of Transplant Experiments in the Native and Introduced Ranges
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Poll, Myriam, Naylor, Bridgett J., Alexander, Jake M., Edwards, Peter J., and Dietz, Hansjörg
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- 2009
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6. Establishment of Parallel Altitudinal Clines in Traits of Native and Introduced Forbs
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Alexander, Jake M., Edwards, Peter J., Poll, Myriam, Parks, Catherine G., and Dietz, Hansjörg
- Published
- 2009
7. The role of arbuscular mycorrhizal fungi in nonnative plant invasion along mountain roads.
- Author
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Clavel, Jan, Lembrechts, Jonas, Alexander, Jake, Haider, Sylvia, Lenoir, Jonathan, Milbau, Ann, Nuñez, Martin A., Pauchard, Anibal, Nijs, Ivan, and Verbruggen, Erik
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INTRODUCED plants ,VESICULAR-arbuscular mycorrhizas ,PLANT invasions ,PHYTOPATHOGENIC fungi ,PLANT-fungus relationships ,FUNGAL colonies ,ECOLOGICAL niche - Abstract
Summary: Plant associated mutualists can mediate invasion success by affecting the ecological niche of nonnative plant species. Anthropogenic disturbance is also key in facilitating invasion success through changes in biotic and abiotic conditions, but the combined effect of these two factors in natural environments is understudied.To better understand this interaction, we investigated how disturbance and its interaction with mycorrhizas could impact range dynamics of nonnative plant species in the mountains of Norway. Therefore, we studied the root colonisation and community composition of arbuscular mycorrhizal (AM) fungi in disturbed vs undisturbed plots along mountain roads.We found that roadside disturbance strongly increases fungal diversity and richness while also promoting AM fungal root colonisation in an otherwise ecto‐mycorrhiza and ericoid‐mycorrhiza dominated environment. Surprisingly, AM fungi associating with nonnative plant species were present across the whole elevation gradient, even above the highest elevational limit of nonnative plants, indicating that mycorrhizal fungi are not currently limiting the upward movement of nonnative plants.We conclude that roadside disturbance has a positive effect on AM fungal colonisation and richness, possibly supporting the spread of nonnative plants, but that there is no absolute limitation of belowground mutualists, even at high elevation. See also the Commentary on this article by Bueno et al., 230: 883–885. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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8. Moving up and over: redistribution of plants in alpine, Arctic, and Antarctic ecosystems under global change.
- Author
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Rew, Lisa J., McDougall, Keith L., Alexander, Jake M., Daehler, Curtis C., Essl, Franz, Haider, Sylvia, Kueffer, Christoph, Lenoir, Jonathan, Milbau, Ann, Nuñez, Martin A., Pauchard, Aníbal, and Rabitsch, Wolfgang
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MOUNTAIN plants ,PLANT species ,INTRODUCED species ,PLANT capacity ,BIODIVERSITY conservation ,INTRODUCED plants ,CHEMICAL plants - Abstract
Extreme abiotic conditions, geographic isolation, and low levels of disturbance have historically provided alpine, Arctic, and Antarctic regions with low input of and relative resistance to the introduction of new species. However, the climate is warming rapidly, concomitant with intense and diversified types of human influence in these cold environments. Consequently, many plant species, both native and nonnative, are now moving or expanding their ranges to higher elevations and latitudes, creating new species interactions and assemblages that challenge biodiversity conservation. Based on our synthesis, many of the same nonnative species invade multiple cold environments, and many more could move up or over from adjoining warmer areas. Transportation networks and the disturbances associated with burgeoning development are responsible for many movements. Prevention and monitoring for nonnative plant species is of paramount importance, and management should be directed toward species that negatively impact ecosystem function or human well-being. Management of native range shifters is more complicated; most movements will be desirable, but some may be locally undesirable. Overall, plant movements into alpine, arctic, and Antarctic areas are going to increase, and management will need to be adaptive because species movements and assemblages of the past will not reflect those of the future. [ABSTRACT FROM AUTHOR]
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- 2020
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9. Earlier phenology of a nonnative plant increases impacts on native competitors.
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Alexander, Jake M. and Levine, Jonathan M.
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INTRODUCED plants , *PLANT phenology , *PLANT competition , *INVASIVE plants , *PLANT adaptation - Abstract
Adaptation to climate is expected to increase the performance of invasive species and their community-level impacts. However, while the fitness gains from adaptation should, in general, promote invader competitive ability, empirical demonstrations of this prediction are scarce. Furthermore, climate adaptation, in the form of altered timing of life cycle transitions, should affect the phenological overlap between nonnative and native competitors, with potentially large, but poorly tested, impacts on native species persistence. We evaluated these predictions by growing native California grassland plants in competition with nonnative Lactuca serriola, a species that flowers earlier in parts of its nonnative range that are drier than its putative European source region. In common garden experiments in southern California with L. serriola populations differing in phenology, plants originating from arid climates bolted up to 48 d earlier than plants from more mesic climates, and selection favored early flowering, supporting an adaptive basis for the phenology cline. The per capita competitive effects of L. serriola from early flowering populations on five early flowering native species were greater than the effects of L. serriolafrom later flowering populations. Consequently, the ability of the native species to increase when rare in competition with L. serriola, as inferred from field-parameterized competition models, declined with earlier L. serriola phenology. Indeed, changes to L. serriolaphenology affected whether or not one native species was predicted to persist in competition with L. serriola. Our results suggest that evolution in response to new climatic conditions can have important consequences for species interactions, and enhance the impacts of biological invasions on natural communities. [ABSTRACT FROM AUTHOR]
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- 2019
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10. Range limits and population dynamics of non-native plants spreading along elevation gradients.
- Author
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Seipel, Tim, Alexander, Jake M., Edwards, Peter J., and Kueffer, Christoph
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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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11. Genetically based differentiation in growth of multiple non-native plant species along a steep environmental gradient.
- Author
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Haider, Sylvia, Kueffer, Christoph, Edwards, Peter, and Alexander, Jake
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INTRODUCED plants ,PLANT species ,PHENOTYPIC plasticity in plants ,GENETIC research ,PLANT genetics ,PLANT growth - Abstract
A non-native plant species spreading along an environmental gradient may need to adjust its growth to the prevailing conditions that it encounters by a combination of phenotypic plasticity and genetic adaptation. There have been several studies of how non-native species respond to changing environmental conditions along latitudinal gradients, but much less is known about elevational gradients. We conducted a climate chamber experiment to investigate plastic and genetically based growth responses of 13 herbaceous non-native plants along an elevational gradient from 100 to 2,000 m a.s.l. in Tenerife. Conditions in the field ranged from high anthropogenic disturbance but generally favourable temperatures for plant growth in the lower half of the gradient, to low disturbance but much cooler conditions in the upper half. We collected seed from low, mid and high elevations and grew them in climate chambers under the characteristic temperatures at these three elevations. Growth of all species was reduced under lower temperatures along both halves of the gradient. We found consistent genetically based differences in growth over the upper elevational gradient, with plants from high-elevation sites growing more slowly than those from mid-elevation ones, while the pattern in the lower part of the gradient was more mixed. Our data suggest that many non-native plants might respond to climate along elevational gradients by genetically based changes in key traits, especially at higher elevations where low temperatures probably impose a stronger selection pressure. At lower elevations, where anthropogenic influences are greater, higher gene flow and frequent disturbance might favour genotypes with broad ecological amplitudes. Thus the importance of evolutionary processes for invasion success is likely to be context-dependent. [ABSTRACT FROM AUTHOR]
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- 2012
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12. Assembly of nonnative floras along elevational gradients explained by directional ecological filtering.
- Author
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Alexander, Jake M., Kueffer, Christoph, Daehler, Curtis C., Edwards, Peter J., Pauchard, Aníbal, and Seipel, Tim
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INTRODUCED species , *ORGANISMS , *INTRODUCED plants , *PLANTS , *ECOLOGY - Abstract
Nonnative species richness typically declines along environmental gradients such as elevation. It is usually assumed that this is because few invaders possess the necessary adaptations to succeed under extreme environmental conditions. Here, we show that nonnative plants reaching high elevations around the world are not highly specialized stress tolerators but species with broad climatic tolerances capable of growing across a wide elevational range. These results contrast with patterns for native species, and they can be explained by the unidirectional expansion of nonnative species from anthropogenic sources at low elevations and the progressive dropping out of species with narrow elevational amplitudes-a process that we call directional ecological filtering. Independent data confirm that climatic generalists have succeeded in colonizing the more extreme environments at higher elevations. These results suggest that invasion resistance is not conferred by extreme conditions at a particular site but determined by pathways of introduction of nonnative species. In the future, increased direct introduction of nonnative species with specialized ecophysiological adaptations to mountain environments could increase the risk of invasion. As well as providing a general explanation for gradients of nonnative species richness and the importance of traits such as phenotypic plasticity for many invasive species, the concept of directional ecological filtering is useful for understanding the initial assembly of some native floras at high elevations and latitudes. [ABSTRACT FROM AUTHOR]
- Published
- 2011
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13. Limits to the niche and range margins of alien species.
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Alexander, Jake M. and Edwards, Peter J.
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ECOLOGICAL niche , *INTRODUCED species , *BIOLOGICAL productivity , *PLANT species , *PLANT genetics , *PLANT ecology , *PLANT population genetics , *ANTHROPOGENIC effects on nature , *INTRODUCED plants - Abstract
We discuss the apparent paradox that while introduced populations often adapt rapidly to conditions in the new range, it is normally assumed that the species’ niche remains unchanged. Focusing on plants, we argue that studies of the niche dynamics of alien species are useful for understanding the constraints acting on species in their native ranges, and vice versa. Most hypotheses about species ecological range margins are more consistent with there being a niche shift than niche stasis in the new range. After reviewing the evidence for niche shifts in alien species, we suggest that the probability of a shift occurring depends primarily upon the ecological and genetic processes limiting the species in its native range. For example, a fundamental niche shift might occur if introduced individuals are released from maladaptive gene flow from central populations, or if genetic diversity is increased by the mixing of individuals from different sources. In addition, other factors such as species characteristics, introduction history and conditions in the new range may also influence whether a niche shift occurs. Based on these considerations, we propose conditions under which niche shifts are most likely. Such understanding is important for predicting and mitigating current and future anthropogenic impacts on species ranges. [ABSTRACT FROM AUTHOR]
- Published
- 2010
- Full Text
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14. Establishment of parallel altitudinal dines in traits of native and introduced forbs.
- Author
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ALEXANDER, JAKE M., EDWARDS, PETER J., POLL, MYRIAM, PARKS, CATHERINE G., and DIETZ, HANSJÖRG
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INTRODUCED plants , *PLANT species , *BIOLOGICAL variation , *PLANT invasions , *PLANT populations , *ECOLOGICAL niche , *BIOLOGICAL adaptation - Abstract
Due to altered ecological and evolutionary contexts, we might expect the responses of alien plants to environmental gradients, as revealed through patterns of trait variation, to differ from those of the same species in their native range. In particular, the spread of alien plant species along such gradients might be limited by their ability to establish clinal patterns of trait variation. We investigated trends in growth and reproductive traits in natural populations of eight invasive Asteraceae forbs along altitudinal gradients in their native and introduced ranges (Valais, Switzerland, and Wallowa Mountains, Oregon, USA). Plants showed similar responses to altitude in both ranges, being generally smaller and having fewer inflorescences but larger seeds at higher altitudes. However, these trends were modified by region-specific effects that were independent of species status (native or introduced), suggesting that any differential performance of alien species in the introduced range cannot be interpreted without a fully reciprocal approach to test the basis of these differences. Furthermore, we found differences in patterns of resource allocation to capitula among species in the native and the introduced areas. These suggest that the mechanisms underlying trait variation, for example, increasing seed size with altitude, might differ between ranges. The rapid establishment of clinal patterns of trait variation in the new range indicates that the need to respond to altitudinal gradients, possibly by local adaptation, has not limited the ability of these species to invade mountain regions. Studies are now needed to test the underlying mechanisms of altitudinal dines in traits of alien species. [ABSTRACT FROM AUTHOR]
- Published
- 2009
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