Trait differentiation between native and introduced populations of the invasive plant Sonchus oleraceus L. (Asteraceae)

Ollivier, Matthias; Kazakou, Elena; Corbin, Maxime; Sartori, Kevin; Gooden, Ben; Lesieur, Vincent; Thomann, Thierry; Martin, Jean

doi:10.3897/neobiota.55.49158

Cited by 14 publications

(12 citation statements)

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“…First, similar recent (Ollivier et al 2020) and classic often‐cited (Maron et al 2004) studies have provided valuable insights without maternal corrections. For example, Ollivier et al (2020) measured 20 plant traits (including germination, seed mass, seed number, plant height, and biomass) in Sonchus oleraceus in a glasshouse experiment, and then evaluated the effects of temperature and precipitation variables on each of the traits. In that study, seeds were collected over 2 yr from 14 populations in nine countries, stored in paper bags with silica gel, and then just sown directly for trait measurements.…”

Section: Methodsmentioning

confidence: 87%

“…Nevertheless, we are still confident in the validity of our experimental design. First, similar recent (Ollivier et al 2020) and classic often-cited (Maron et al 2004) studies have provided valuable insights without maternal corrections. For example, Ollivier et al (2020) measured 20 plant traits (including germination, seed mass, seed number, plant height, and biomass) in Sonchus oleraceus in a glasshouse experiment, and then evaluated the effects of temperature and precipitation variables on each of the traits.…”

Section: Methodsmentioning

confidence: 98%

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Time‐traveling seeds reveal that plant regeneration and growth traits are responding to climate change

Everingham

Offord

Sabot

et al. 2021

Ecology

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Studies assessing the biological impacts of climate change typically rely on longterm, historic data to measure trait responses to climate through time. Here, we overcame the problem of absent historical data by using resurrected seeds to capture historic plant-trait data for a number of plant regeneration and growth traits. We collected seed and seedling trait measurements from resurrected historic seeds and compared these with modern seed and seedling traits collected from the same species in the same geographic location. We found a total of 43 species from southeastern Australia for which modern/historic seed pairs could be located. These species were located in a range of regions that have undergone different amounts of climate change across a range of temperature, precipitation, and extreme measures of climate. There was a correlation between the amount of change in climate metrics, and the amount of change in plant traits. Using stepwise model selection, we found that for all regeneration and growth trait changes (except change in stem density), the most accurate model selected at least two measures of climate change. Changes in extreme measures of climate, such as heatwave duration and changes in climate variability, were more strongly related to changes in regeneration and growth traits than changes in mean climate metrics. Across our species, for every 5% increase in temperature variability, there was a threefold increase in the probability of seed viability and seed germination success. An increase of 1 d in the maximum duration of dry spells through time led to a 1.5-fold decrease in seed viability and seeds became 30% flatter/thinner. Regions where the maximum heatwave duration had increased by 10 d saw a 1.35-cm decrease in seedling height and a 1.04-g decrease in seedling biomass. Rapid responses in plant traits to changes in climate may be possible; however, it is not clear whether these changes will be fast enough for plants to keep pace with future climate change.

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Section: Methodsmentioning

confidence: 87%

Section: Methodsmentioning

confidence: 98%

Time‐traveling seeds reveal that plant regeneration and growth traits are responding to climate change

Everingham

Offord

Sabot

et al. 2021

Ecology

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“…Mature weed plants in each plot were identified, and the number of capitula were recorded to generate an estimate of the average number of capitula per plant in each plot: if fewer than five plants were found in a plot, the number of capitula on each was recorded, and if more than five plants were identified, five were randomly selected from the plot for capitula counts. These numbers were multiplied by the number of plants per plot from the earlier posttreatment weed counts and an estimated average of 170 seeds per capitula based on the literature (Mobli et al 2020;Ollivier et al 2020). Due to low weed densities in 2018 at RS2, an extra weed density assessment was completed before presowing herbicide treatments in 2019.…”

Section: Experimental Design and Samplingmentioning

confidence: 99%

Can rotations improve management of herbicide-resistant annual sowthistle (Sonchus oleraceus) and prickly lettuce (Lactuca serriola) in lentil production systems of southern Australia?

et al. 2020

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In southern Australia, annual sowthistle and prickly lettuce have become more prevalent following the adoption of reduced tillage cropping systems. They are especially problematic in lentil and other pulse crops, which are weakly competitive and have few herbicide options available for POST control of broadleaf weeds. This study aimed to evaluate the influence of management in a previous cereal crop on weed densities in a subsequent crop. At two field sites, crop seeding density and POST herbicide treatments (a conventional choice that included metsulfuron-methyl and MCPA; and a proactive choice that included bromoxynil, picolinafen, and MCPA) were applied to a wheat crop, and weed density was assessed at the beginning of the following season to measure for a legacy effect of the treatments. Study site populations were also screened for herbicide resistance and were found to have high (≥90% survival) ALS inhibitor resistance. Crop competition treatments had no effect on weed populations, and effects of herbicide treatment were significant at only one of the sites. At this site, both herbicide treatments had lower weed densities than the nontreated in the first year, but the legacy effect was only significant for annual sowthistle density in the proactive treatment. At both sites, even where weeds were extremely sparse or completely controlled following herbicide treatment in the first year, moderate densities were observed the following year, indicating that colonization from the seedbank or adjacent areas could be contributing to weed numbers. Weed density assessments and accurate knowledge of the herbicide resistance status of target weeds should guide herbicide selection to maximize control.

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“…More research is needed to determine the relative fitness advantages of admixed versus non-admixed genotypes of S. oleraceus in Australia over several generations (Cristescu, 2015). However, a recent study by Ollivier et al (2020) showed that S. oleraceus plants from S8). In other Asteraceae species that have become successful invaders, there is similar evidence of repeated introductions from different geographical areas (Eriksen et al, 2015;van Boheemen et al, 2017).…”

Section: Introductions From the Native Range And Admixturementioning

confidence: 99%

“…These human-mediated introductions are likely to have promoted admixture from multiple sources followed by recombination and selection for multiple traits in introduced Australian S. oleraceus plants (Ollivier et al, 2020).…”

Section: Introductions From the Native Range And Admixturementioning

confidence: 99%

Population genomics reveal multiple introductions and admixture of Sonchus oleraceus in Australia

Encinas‐Viso

Morin

Raghu

et al. 2022

Diversity and Distributions

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Aim The goal of this study was to investigate the invasion history of the weed Sonchus oleraceus in Australia by comparing the population genetic structure of individuals at different locations in Australia, and in the most likely areas of origin in the native range. Location Samples were collected in Europe and Morocco, North Africa (27 locations), and Australia (17 locations). Methods We performed population genetic analyses using a large dataset comprising 2883 single nucleotide polymorphism markers from 547 plant samples and investigated the invasion history of S. oleraceus with Approximate Bayesian Computation and Random Forest classification algorithms. We compared single and multiple invasion scenarios considering admixture having occurred before and after introduction. Results Our results revealed high levels of inbreeding within sampling locations in the two ranges. Analyses also showed that S. oleraceus was possibly introduced to Australia at least twice: a first introduction around 1000 years ago before British settlement and a more recent introduction (~65 years ago) from Europe and North Africa. We also found evidence of post‐introduction admixture and a potential reintroduction of S. oleraceus from Australia back to its native range. Main conclusions We conclude that the invasion history of S. oleraceus into Australia is probably historic (i.e. prior to British settlements) and complex showing recent evidence of post‐introduction admixture. The complex invasion history of S. oleraceus in Australia poses challenges for the search of potential biological control agents.

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Trait differentiation between native and introduced populations of the invasive plant Sonchus oleraceus L. (Asteraceae)

Cited by 14 publications

References 100 publications

Time‐traveling seeds reveal that plant regeneration and growth traits are responding to climate change

Time‐traveling seeds reveal that plant regeneration and growth traits are responding to climate change

Can rotations improve management of herbicide-resistant annual sowthistle (Sonchus oleraceus) and prickly lettuce (Lactuca serriola) in lentil production systems of southern Australia?

Population genomics reveal multiple introductions and admixture of Sonchus oleraceus in Australia

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