Your search keyword '"Müller-Schärer, Heinz"' showing total 16 results

1. Invasion syndromes: a systematic approach for predicting biological invasions and facilitating effective management

Author

Novoa, Ana, Richardson, David M., Pyšek, Petr, Meyerson, Laura A., Bacher, Sven, Canavan, Susan, Catford, Jane A., Čuda, Jan, Essl, Franz, Foxcroft, Llewellyn C., Genovesi, Piero, Hirsch, Heidi, Hui, Cang, Jackson, Michele C., Kueffer, Christoph, Le Roux, Johannes J., Measey, John, Mohanty, Nitya P., Moodley, Desika, Müller-Schärer, Heinz, Packer, Jasmin G., Pergl, Jan, Robinson, Tamara B., Saul, Wolf-Christian, Shackleton, Ross T., Visser, Vernon, Weyl, Olaf L. F., Yannelli, Florencia A., and Wilson, John R. U.

Published

2020

2. Epiblema minutana (Lepidoptera, Tortricidae) in Israel: Promise or Peril?

Author

Augustinus, Benno A., Nussbaum, Nadav, Yair, Yifat, Harari, Ally, Yaacoby, Tuvia, Müller-Schärer, Heinz, Schaffner, Urs, and Rubin, Baruch

Subjects

WEEDS, TORTRICIDAE, BIOLOGICAL pest control agents, NOXIOUS weeds, SUNFLOWERS, PARTHENIUM hysterophorus, LEPIDOPTERA

Abstract

Parthenium weed (Parthenium hysterophorus L.) is a noxious weed and a flagship invasive that has been spreading throughout Israel and the Palestinian Authority since 1980. In other regions affected by this invader, parthenium weed has been managed through classical biological control releases of Epiblema strenuana, a stem-galling tortricid moth native to North America. More recently, a congeneric moth, Epiblema minutana has been identified from Israel. To better understand the implications of E. minutana for controlling parthenium weed, we investigated the spread of E. minutana within Israel and the Palestinian Authority from 2012 to 2019 and explored its host range. We used a series of no-choice experiments in field cages to evaluate damage on naturalized Ambrosia spp., Xanthium italicum and parthenium weed as well as potential non-target, commercial cultivars of sunflower (Helianthus annuus L.) and niger (Guizotia abysinnica (L. f.) Cassini). We also evaluated damage in the field, where we found substantial gall formation on Ambrosia spp., but none on P. hysterophorus or other genera. The geographical distribution increased from an estimated 424 km² in 2017 to 1671 km² in 2019. While E. minutana shows promise as a biological control agent of Ambrosia spp. and does not attack the oil crops sunflower and niger, it is not a suitable biological control agent of parthenium weed. [ABSTRACT FROM AUTHOR]

Published

2023

3. Climate warming can reduce biocontrol efficacy and promote plant invasion due to both genetic and transient metabolomic changes.

Author

Sun, Yan, Züst, Tobias, Silvestro, Daniele, Erb, Matthias, Bossdorf, Oliver, Mateo, Pierre, Robert, Christelle, Müller‐Schärer, Heinz, and Vila, Montserrat

Subjects

METABOLOMICS, AMBROSIA artemisiifolia, PLANT populations, PLANT invasions, BIOMASS, CLIMATE change

Abstract

Climate change may affect plant–herbivore interactions and their associated ecosystem functions. In an experimental evolution approach, we subjected replicated populations of the invasive Ambrosia artemisiifolia to a combination of simulated warming and herbivory by a potential biocontrol beetle. We tracked genomic and metabolomic changes across generations in field populations and assessed plant offspring phenotypes in a common environment. Using an integrated Bayesian model, we show that increased offspring biomass in response to warming arose through changes in the genetic composition of populations. In contrast, increased resistance to herbivory arose through a shift in plant metabolomic profiles without genetic changes, most likely by transgenerational induction of defences. Importantly, while increased resistance was costly at ambient temperatures, warming removed this constraint and favoured both vigorous and better defended plants under biocontrol. Climate warming may thus decrease biocontrol efficiency and promote Ambrosia invasion, with potentially serious economic and health consequences. [ABSTRACT FROM AUTHOR]

Published

2022

4. In-season leaf damage by a biocontrol agent explains reproductive output of an invasive plant species

Author

Augustinus, Benno Andreas, Lommen, Suzanne, Fogliatto, Silvia, Vidotto, Francesco, Smith, Tessa R, Horvath, David, Bonini, Maira, Gentili, Rodolfo, Citterio, Sandra, Müller-Schärer, Heinz, Schaffner, Urs, Augustinus, B, Lommen, S, Fogliatto, S, Vidotto, F, Smith, T, Horvath, D, Bonini, M, Gentili, R, Citterio, S, Muller-Scharer, H, and Schaffner, U

Subjects

BIO/03 - BOTANICA AMBIENTALE E APPLICATA, herbivory, fungi, biological invasions, common ragweed, food and beverages, Ambrosia artemisiifolia, biological invasions, classical biological control, common ragweed, herbivory, Ophraella communa, classical biological control, BIO/01 - BOTANICA GENERALE, lcsh:Biology (General), Ophraella communa, Ambrosia artemisiifolia, Biological invasions, Classical biological control, Common ragweed, Herbivory, Ophraella communa, lcsh:QH301-705.5, Ambrosia artemisiifolia biological invasions classical biological control common ragweed herbivory Ophraella communa, Ambrosia artemisiifolia

Abstract

One of the biggest challenges in classical biological control of invasive weeds is predicting the likelihood of success. Ambrosia artemisiifolia, a North American plant species that has become invasive in Europe, causes economic losses due to health problems resulting from its huge amount of highly allergenic pollen and as a weed to agricultural crops resulting from high seed densities. Here we assessed whether the pollen and seed output of the annual A. artemisiifolia (at the end of the season) is related to in-season abundance of, or damage by, the accidentally introduced biological control agent Ophraella communa. We monitored the growth and leaf damage of individually labelled A. artemisiifolia plants at four locations in Northern Italy and recorded abundance of different O. communa life stages at regular intervals. We found that the in-season level of leaf damage by O. communa consistently helped to explain seed production in combination with plant volume and site throughout the season. Feeding damage, plant volume and site also explained pollen production by A. artemisiifolia six weeks before male flower formation. At three out of four sites, plants with more than 10% leaf damage in mid-June or early July had a very low likelihood of seed formation. Leaf damage proved to be a better explanatory variable than O. communa abundance. Our results suggest that the monitoring of the in-season leaf damage can help to project the local impact of O. communa on A. artemisiifolia at the end of the season and thus inform management regarding the needs for additional measures to control this prominent invader.

Published

2020

5. Climatic suitability ranking of biological control candidates: a biogeographic approach for ragweed management in Europe

Author

Sun, Yan, Brönnimann, Olivier, Roderick, George K., Poltavsky, Alexander, Lommen, Suzanne T. E., and Müller-Schärer, Heinz

Subjects

climate change, Ambrosia artemisiifolia, biological invasions, niche overlap, species distribution model, lcsh:QH540-549.5, lcsh:Ecology

Abstract

Biological control using natural antagonists has been a most successful management tool against alien invasive plants that threaten biodiversity. The selection of candidate agents remains a critical step in a biocontrol program before more elaborate and time- consuming experiments are conducted. Here, we propose a biogeographic approach to identify candidates and combinations of candidates to potentially cover a large range of the invader. We studied Ambrosia artemisiifolia (common ragweed), native to North America (NA) and invasive worldwide, and six NA biocontrol candidates for the introduced Europe (EU) range of ragweed, both under current and future bioclimatic conditions. For the first time, we constructed species distribution models based on worldwide occurrences and important bioclimatic variables simultaneously for a plant invader and its biocontrol candidates in view of selecting candidates that potentially cover a large range of the target invader. Ordination techniques were used to explore climatic constraints of each species and to perform niche overlap tests with ragweed. We show a large overlap in climatic space between candidates and ragweed, but a considerable discrepancy in geographic range overlap between EU (31.4%) and NA (83.3%). This might be due to niche unfilling and expansion of ragweed in EU and the fact that habitats with high ragweed occurrences in EU are rare in NA and predicted to be unsuitable for the candidates. Total geographic range of all candidates combined is expected to decrease under climate change in both ranges, but they will respond differently. The relative geographic coverage of a plant invader by biocontrol candidates at home is largely transferable to the introduced range, even when the invader shifts its niche. Our analyses also identified which combination of candidates is expected to cover the most area and for which abiotic conditions to select in order to develop climatically adapted strains for particular regions, where ragweed is currently unlikely to be controlled.

Published

2017

6. Rapid genomic and phenotypic change in response to climate warming in a widespread plant invader.

Author

Sun, Yan, Bossdorf, Oliver, Grados, Ramon D., Liao, ZhiYong, and Müller‐Schärer, Heinz

Subjects

INVASIVE plants, CLIMATE change, AMBROSIA artemisiifolia, PHYTOGEOGRAPHY, NUCLEOTIDE sequence, PLANT capacity

Abstract

Predicting plant distributions under climate change is constrained by our limited understanding of potential rapid adaptive evolution. In an experimental evolution study with the invasive common ragweed (Ambrosia artemisiifolia L.) we subjected replicated populations of the same initial genetic composition to simulated climate warming. Pooled DNA sequencing of parental and offspring populations showed that warming populations experienced greater genetic divergence from their parents, than control populations. In a common environment, offspring from warming populations showed more convergent phenotypes in seven out of nine plant traits, with later flowering and larger biomass, than plants from control populations. For both traits, we also found a significantly higher ratio of phenotypic to genetic differentiation across generations for warming than for control populations, indicating stronger response to selection under warming conditions. As a measure for evolutionary rate, the phenotypic and sequence divergence between generations were assessed using the Haldane metric. Our approach combining comparisons between generations (allochronic) and between treatments (synchronic) in an experimental evolutionary field study, and linking population genomic data with phenotyping analyses provided a powerful test to detect rapid responses to selection. Our findings demonstrate that ragweed populations can rapidly evolve in response to climate change within a single generation. Short‐term evolutionary responses to climate change may aggravate the impact of some plant invaders in the future and should be considered when making predictions about future distributions and impacts of plant invaders. [ABSTRACT FROM AUTHOR]

Published

2020

7. In-season leaf damage by a biocontrol agent explains reproductive output of an invasive plant species.

Author

Augustinus, Benno A., Lommen, Suzanne T. E., Fogliatto, Silvia, Vidotto, Francesco, Smith, Tessa, Horvath, David, Bonini, Maira, Gentili, Rodolfo F., Citterio, Sandra, Müller-Schärer, Heinz, and Schaffner, Urs

Subjects

INTRODUCED species, CROPS, PLANT species, BIOLOGICAL weed control, BIOLOGICAL pest control agents, INVASIVE plants, AMBROSIA artemisiifolia

Abstract

One of the biggest challenges in classical biological control of invasive weeds is predicting the likelihood of success. Ambrosia artemisiifolia, a North American plant species that has become invasive in Europe, causes economic losses due to health problems resulting from its huge amount of highly allergenic pollen and as a weed to agricultural crops resulting from high seed densities. Here we assessed whether the pollen and seed output of the annual A. artemisiifolia (at the end of the season) is related to in-season abundance of, or damage by, the accidentally introduced biological control agent Ophraella communa. We monitored the growth and leaf damage of individually labelled A. artemisiifolia plants at four locations in Northern Italy and recorded abundance of different O. communa life stages at regular intervals. We found that the in-season level of leaf damage by O. communa consistently helped to explain seed production in combination with plant volume and site throughout the season. Feeding damage, plant volume and site also explained pollen production by A. artemisiifolia six weeks before male flower formation. At three out of four sites, plants with more than 10% leaf damage in mid-June or early July had a very low likelihood of seed formation. Leaf damage proved to be a better explanatory variable than O. communa abundance. Our results suggest that the monitoring of the in-season leaf damage can help to project the local impact of O. communa on A. artemisiifolia at the end of the season and thus inform management regarding the needs for additional measures to control this prominent invader. [ABSTRACT FROM AUTHOR]

Published

2020

8. Biological invasion of oxeye daisy (Leucanthemum vulgare) in North America: Pre-adaptation, post-introduction evolution, or both?

Author

Stutz, Sonja, Mráz, Patrik, Hinz, Hariet L., Müller-Schärer, Heinz, and Schaffner, Urs

Subjects

BIOLOGICAL invasions, LEUCANTHEMUM vulgare, BIOLOGICAL adaptation, PLANT morphology, PLANT species

Abstract

Species may become invasive after introduction to a new range because phenotypic traits pre-adapt them to spread and become dominant. In addition, adaptation to novel selection pressures in the introduced range may further increase their potential to become invasive. The diploid Leucanthemum vulgare and the tetraploid L. ircutianum are native to Eurasia and have been introduced to North America, but only L. vulgare has become invasive. To investigate whether phenotypic differences between the two species in Eurasia could explain the higher abundance of L. vulgare in North America and whether rapid evolution in the introduced range may have contributed to its invasion success, we grew 20 L. vulgare and 21 L. ircutianum populations from Eurasia and 21 L. vulgare populations from North America under standardized conditions and recorded performance and functional traits. In addition, we recorded morphological traits to investigate whether the two closely related species can be clearly distinguished by morphological means and to what extent morphological traits have changed in L. vulgare post-introduction. We found pronounced phenotypic differences between L. vulgare and L. ircutianum from the native range as well as between L. vulgare from the native and introduced ranges. The two species differed significantly in morphology but only moderately in functional or performance traits that could have explained the higher invasion success of L. vulgare in North America. In contrast, leaf morphology was similar between L. vulgare from the native and introduced range, but plants from North America flowered later, were larger and had more and larger flower heads than those from Eurasia. In summary, we found litte evidence that specific traits of L. vulgare may have pre-adapted this species to become more invasive than L. ircutianum, but our results indicate that rapid evolution in the introduced range likely contributed to the invasion success of L. vulgare. [ABSTRACT FROM AUTHOR]

Published

2018

9. BIOGEOGRAPHIC EFFECTS ON EARLY ESTABLISHMENT OF AN INVASIVE ALIEN PLANT.

Author

Sun, Yan, Müller‐Schärer, Heinz, Maron, John L., and Schaffner, Urs

Subjects

*BIOGEOGRAPHY, *ASTERACEAE, *BIOLOGICAL invasions, *CENTAUREA, *INTRODUCED species, *INVASIVE plants

Abstract

Premise of the study: Biotic resistance is often studied in the context of how interactions between native biota and invading species influence the success of those invaders. Seldom, however, is the strength of "resistance" compared biogeographically, where the ability of a species to impede invader establishment is contrasted between an invader's native and introduced recipient community. Methods: We conducted an experiment to examine how community diversity influences seedling recruitment of a plant invader where it is native and contrasted with results previously published from introduced ranges. In Switzerland, we created recipient communities that varied in species and functional richness and invaded them, or not, with seeds of Centaurea stoebe, a native European plant that has been previously used in an identical experiment in North America, where it is a prominent invader. Key results: The biogeographic comparison revealed that the recipient community largely prevented C. stoebe seedling establishment at home (Switzerland), but not away (Montana, USA), and that diversity of the resident vegetation did not contribute to the effects observed in the introduced range. Conclusions: Our results provide evidence that differences in the biogeographic conditions and/or overall level of competition of resident community between the native and introduced range considerably suppresses seedling recruitment of the invasive plant, rather than resident diversity itself. In the case of C. stoebe, the surprisingly low establishment success in the experiments conducted in the native compared with the introduced range is likely to be influenced by the higher level of competition with resident community, by abiotic environmental conditions or interactions between these two factors in the native range. Release from factors suppressing seedling recruitment at home may contribute to the successful invasion of C. stoebe in North America. [ABSTRACT FROM AUTHOR]

Published

2015

10. Drought tolerance and plasticity in the invasive knapweed Centaurea stoebe s.l. (Asteraceae): effect of populations stronger than those of cytotype and range.

Author

Mráz, Patrik, Tarbush, Elham, and Müller-Schärer, Heinz

Subjects

DROUGHT tolerance, CARBON isotopes, MATERIAL plasticity, BIOMASS, TETRAPLOIDY

Abstract

Background and Aims Spotted knapweed (Centaurea stoebe s.l., Asteraceae) is native to Europe, where it occurs as a diploid (2xEU) and tetraploid cytotype (4xEU), but so far only the tetraploid has been reported in the introduced range in North America (4xNA). In previous studies, significant range shifts have been found towards drier climates in 4xEU compared with 2xEU, and in 4xNA when compared with the native range. In addition, 4x plants showed thicker leaves and reduced specific leaf area compared with 2x plants, suggesting higher drought tolerance in 4x plants. It is thus hypothesized that the 4x cytotype might be better pre-adapted to drought than the 2x, and the 4xNA better adapted than the 4xEU due to post-introduction selection. Methods Plants of the three geocytotypes (2xEU, 4xEU and 4xNA ), each represented by six populations, were subjected to three water treatments over 6 weeks in a greenhouse experiment. Plasticity and reaction norms of above- and below-ground biomasses and their ratio, survival rate, stomatal conductance and carbon isotope discrimination were analysed using linear and generalized linear mixed effect models. Key Results and Conclusions Above-ground and total biomasses of European tetraploids were slightly less affected by drought than those of European diploids, and 4xEU plants maintained higher levels of stomatal conductance under moderate drought than 4xNA plants, thus supporting the pre-adaptation but not the post-introduction evolution hypothesis. Plasticity indexes for most of the traits were generally higher in 2xEU and 4xNA than in 4xEU plants, but these differences were not or were only marginally significant. Interestingly, the effect of population origin and its interaction with treatment was more important than the effects of geocytotype and range. Population means for the control treatment showed several significant associations either with latitude or some aspect of climatic data, suggesting evolution of local adaptations, especially within the 2xEU and 4xEU geocytotypes. [ABSTRACT FROM AUTHOR]

Published

2014

11. Increased population growth rate in invasive polyploid Centaurea stoebe in a common garden.

Author

Hahn, Min A., Buckley, Yvonne M., Müller-Schärer, Heinz, and Gurevitch, Jessica

Subjects

POPULATION, POLYPLOIDY, CENTAUREA, BIOLOGICAL invasions, TETRAPLOIDY, DIPLOIDY, KNAPWEEDS

Abstract

Biological invasions are inherently demographic processes, but trait differences between native and introduced genotypes are rarely linked to population growth rates. Native European Centaurea stoebe occurs as two cytotypes with different life histories (monocarpic diploids, polycarpic tetraploids); however, only tetraploids have been found in its introduced range in North America. In a common garden experiment using artificial populations, we compared the demographic performance of the three geo-cytotypes in the presence and absence of a specialist herbivore using periodic matrix models. We found no difference in population growth rate between the two European cytotypes and no significant effects of herbivory in all geo-cytotypes. However, there was a pronounced increase in population growth rate for North American compared with European tetraploids due to increased seed production and juvenile establishment. These results suggest that genetic drift or rapid evolution, rather than pre-adaptation through polyploidy may explain the invasion success of tetraploids. [ABSTRACT FROM AUTHOR]

Published

2012

12. Plant invasions, generalist herbivores, and novel defense weapons.

Author

Schaffner, Urs, Ridenour, Wendy M., Wolf, Vera C., Bassett, Thomas, Müller, Caroline, Müller-Schärer, Heinz, Sutherland, Steve, Lortie, Christopher J., and Callaway, Ragan M.

Subjects

PLANT invasions, INVERTEBRATES, HERBIVORES, INTRODUCED plants, NATIVE plants

Abstract

One commonly accepted mechanism for biological invasions is that species, after introduction to a new region, leave behind their natural enemies and therefore increase in distribution and abundance. However, which enemies are escaped remains unclear. Escape from specialist invertebrate herbivores has been examined in detail, but despite the profound effects of generalist herbivores in natural communities their potential to control invasive species is poorly understood. We carried out parallel laboratory feeding bioassays with generalist invertebrate herbivores from the native (Europe) and from the introduced (North America) range using native and nonnative tetraploid populations of the invasive spotted knapweed, Centaurea stoebe. We found that the growth of North American generalist herbivores was far lower when feeding on C. stoebe than the growth of European generalists. In contrast, North American and European generalists grew equally well on European and North American tetraploid C. stoebe plants, lending no support for an evolutionary change in resistance of North American tetraploid C. stoebe populations against generalist herbivores. These results suggest that biogeographical differences in the response of generalist herbivores to novel plant species have the potential to affect plant invasions. [ABSTRACT FROM AUTHOR]

Published

2011

13. POLYPLOIDY IN PHENOTYPIC SPACE AND INVASION CONTEXT: A MORPHOMETRIC STUDY OF CENTAUREA STOEBE S.L.

Author

Mráz, Patrik, Bourchier, Robert S., Treier, Urs A., Schaffner, Urs, and Müller-Schärer, Heinz

Subjects

POLYPLOIDY, PHENOTYPES, MORPHOMETRICS, CENTAUREA, ASTERACEAE, BIOLOGICAL invasions, FLOW cytometry, SPOTTED knapweed, PLANT morphology

Abstract

The taxonomy of the Centaurea stoebe complex is controversial. Diploid and tetraploid plants occur in its native European range, but to date only tetraploids have been recorded from its introduced range in North America. We examined morphological differentiation of C. stoebe using multivariate and univariate approaches to clarify the taxonomic status of the known cytotypes. We measured more than 40 morphological traits on plants originating from 78 populations, grown from seed under uniform glasshouse conditions. The ploidy of almost 300 plants from 2 native and 20 introduced populations from Canada was assessed to test for the absence of diploids from North America. Finally, we explored whether postintroduction processes have resulted in phenotypic changes in introduced plants which may have contributed to the invasion success of C. stoebe. Morphometric analyses showed a clear separation of 2x and 4x plants and thus supported recognition of both cytotypes as separate taxa. Differences in the life cycle, the number of florets, the shape of capitula, and the shape of young rosette leaves were the best discriminant characters. Only minor differences were found between native and introduced tetraploids. All plants from the introduced range except for one hexaploid were found to be tetraploid. Rare diploids from Canada were identified as Centaurea diffusa or Centaurea psamogenna. [ABSTRACT FROM AUTHOR]

Published

2011

14. Polyploidy and invasion success: trait trade-offs in native and introduced cytotypes of two Asteraceae species.

Author

Thébault, Aurélie, Gillet, François, Müller-Schärer, Heinz, and Buttler, Alexandre

Subjects

PLANT species, GENOTYPE-environment interaction, POLYPLOIDY, BIOLOGICAL invasions, POPULATION biology

Abstract

Invasion success is favoured by the introduction of pre-adapted genotypes. In addition, novel pressures in the introduced range may lead to phenotypic changes related to fitness or competitive ability of introduced plants. Polyploidy appears to be over-represented in invasive plants, but differences between cytotypes in growth strategies including trade-offs among plant traits have received little attention so far in the context of biological invasions. We grew Centaurea stoebe L. and Senecio inaequidens D.C. in a greenhouse experiment to test for differences in fitness (shoot biomass, reproductive output) and competitive ability (vegetative size, specific leaf area, leaf dry matter content, root-shoot ratio) between diploid and polyploid cytotypes as well as between native and introduced plants. For both species, diploid and tetraploid genotypes occur in the native range, whereas only tetraploids are present in the introduced range. In the native range of both species, diploid and tetraploid genotypes had different growth strategies. Tetraploid genotypes of C. stoebe and S. inaequidens had, respectively, higher specific leaf area and stem height than diploid ones. Thus, for both species, native tetraploids appeared more competitive than native diploids, which could explain, at least partially, the invasion success of the pre-adapted tetraploid genotypes. The comparison of native and introduced tetraploid genotypes revealed differences in traits linked to competitive ability, which could be linked to novel selection in the new environment. In S. inaequidens, we found evidence for a competition-colonisation trade-off, whereas persistence of C. stoebe in the new range seemed to be linked to a competition-defence trade-off. [ABSTRACT FROM AUTHOR]

Published

2011

15. Evidence for a combination of pre-adapted traits and rapid adaptive change in the invasive plant Centaurea stoebe.

Author

Henery, Martin L., Bowman, Gillianne, Mráz, Patrik, Treier, Urs A., Gex-Fabry, Emilie, Schaffner, Urs, and Müller-Schärer, Heinz

Subjects

BIOLOGICAL invasions, PLANT life cycles, PLANT invasions, SPOTTED knapweed, INVASIVE plants, GENETIC polymorphisms

Abstract

1. Introduced plants have the potential to rapidly evolve traits of ecological importance that may add to their innate potential to become invasive. During invasions, selection may favour genotypes that are already pre-adapted to conditions in the new habitat and, over time, alter the characteristics of subsequent generations. 2. Spotted knapweed ( Centaurea stoebe) occurs in two predominantly spatially separated cytotypes in its native range (Europe–Western Asia), but currently only the tetraploid form has been confirmed in the introduced range (North America), where it is invasive. We used several common garden experiments to examine, across multiple populations, whether tetraploids and diploids from the native range differ in life cycle, leaf traits and reproductive capacity and if such differences would explain the predominance of tetraploids and their advance into new habitats in the introduced range. We also compared the same traits in tetraploids from the native and introduced range to determine whether any rapid adaptive changes had occurred since introduction that may have enhanced invasive potential of the species in North America. 3. We found tetraploids had lower specific leaf area, less lamina dissection and fewer, narrower leaves than diploids. Diploids exhibited a monocarpic life cycle and produced few if any accessory rosettes. Diploids produced significantly more seeds per capitulum and had more capitula per plant than tetraploids. In contrast, the vast majority of European tetraploids continued to flower in both seasons by regenerating from multiple secondary rosettes, demonstrating a predominantly polycarpic life cycle. 4. During early growth tetraploids from North America achieved greater biomass than both tetraploids and diploids from the native range but this did not manifest as larger above-ground biomass at maturity. In North American tetraploids there was also evidence of a shift towards a more strictly polycarpic life cycle, less leaf dissection, greater carbon investment per leaf, and greater seed production per capitulum. 5. Synthesis. Our results suggest that the characteristics of tetraploid C. stoebe pre-adapted them (compared to diploid conspecifics) for spread and persistence of the species into habitats in North America characterized by a more continental climate. After the species’ introduction, small but potentially important shifts in tetraploid biology have occurred that may have contributed significantly to successful invasion. [ABSTRACT FROM AUTHOR]

Published

2010

16. Predicting impact of a biocontrol agent: integrating distribution modeling with climate‐dependent vital rates.

Author

Augustinus, Benno, Sun, Yan, Beuchat, Carine, Schaffner, Urs, and Müller‐Schärer, Heinz

Subjects

VITAL statistics, BIOLOGICAL pest control agents, AMBROSIA artemisiifolia, EGG incubation, SPECIES distribution, HUMIDITY

Abstract

Species distribution models can predict the suitable climatic range of a potential biological control agent (BCA), but they provide little information on the BCA's potential impact. To predict high population buildup, a prerequisite of biocontrol impact, studies are needed that assess the effect of environmental factors on vital rates of a BCA across the environmental gradient of the BCA's suitable habitats, especially for the region where the BCA is considered for field release. We extended a published species distribution model with climate‐dependent vital rates of Ophraella communa, a recently and accidentally introduced potential BCA of common ragweed, Ambrosia artemisiifolia in Europe. In field and laboratory experiments, we collected data on climate‐dependent parameters assumed to be the most relevant for the population buildup of O. communa, i.e., temperature driving the number of generations per year and relative humidity (RH) determining egg hatching success. We found that O. communa concluded one generation in 334 cumulative degree days, and that egg hatching success strongly decreased from > 80% to < 20% when RH drops from 55% to 45% during the day. We used these values to spatially explicitly project population densities across the European range suitable for both A. artemisiifolia and the beetle and found that the present distribution of the beetle in Europe is within the range with the highest projected population growth. The highest population density of O. communa was predicted for northern Italy and parts of western Russia and western Georgia. Field observations of high impact on A. artemisiifolia with records of 80% aerial pollen reduction in the Milano area since the establishment of O. communa are in line with these predictions. The relative importance of temperature and RH on the population density of O. communa varies considerably across its suitable range in Europe. We propose that the combined statistical and mechanistic approach outlined in this paper helps to more accurately predict the potential impact of a weed BCA than a species distribution model alone. Identifying the factors limiting the population buildup of a BCA across the suitable range allows implementation of more targeted release and management strategies to optimize biocontrol efficacy. [ABSTRACT FROM AUTHOR]

Published

2020