Residence time, native range size, and genome size predict naturalization among angiosperms introduced to Australia

Why do some species occur in small, restricted areas, while others are distributed globally? Environmental heterogeneity increases with area and so does the number of species. Hence, diverse biotic and abiotic conditions across large ranges may lead to specific adaptations that are often linked to a species’ genome size and chromosome number. Therefore, a positive association between genome size and geographic range is anticipated. Moreover, high cognitive ability in organisms would be favored by natural selection to cope with the dynamic conditions within large geographic ranges. Here, we tested these hypotheses in birds—the most mobile terrestrial vertebrates—and accounted for the effects of various confounding variables, such as body mass, relative brain mass, and geographic latitude. Using phylogenetic generalized least squares and phylogenetic confirmatory path analysis, we demonstrated that range size is positively associated with bird genome size but probably not with chromosome number. Moreover, relative brain mass had no effect on range size, whereas body mass had a possible weak and negative effect, and range size was larger at higher geographic latitudes. However, our models did not fully explain the overall variation in range size. Hence, natural selection may impose larger genomes in birds with larger geographic ranges, although there may be additional explanations for this phenomenon.

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The genetic variation in giant buttercup in New Zealand pastures

New Zealand Plant Protection ◽

10.30843/nzpp.2015.68.5878 ◽

2015 ◽

Vol 68 ◽

pp. 112-117 ◽

Cited By ~ 3

Author(s):

G.J. Houliston ◽

D.F. Goeke ◽

L.A. Smith ◽

S.V. Fowler

Keyword(s):

Genetic Variation ◽

New Zealand ◽

Genome Size ◽

Biological Agents ◽

Native Range ◽

Weed Species ◽

Widespread Species ◽

Northern Norway ◽

Control Programmes ◽

Ranunculus Acris

Giant buttercup (Ranunculus acris L) is a widespread species that ranges in latitude from northern Norway to Morocco in the native range and has a large naturalised range in several countries including New Zealand Like many weed species with wide natural distributions R acris is a complex made up of different genotypes and races across the native range This paper shows R acris in New Zealand has high chloroplast diversity and variation in genome size even within populations indicating that introduced material was diverse Although it is not yet possible to determine the origin of R acris populations in New Zealand preliminary comparisons to R acris sourced from other countries are presented The importance of identifying the correct origin of naturalised species before undertaking control programmes especially where biological agents will be employed is discussed

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Predicting plant invasiveness from native range size: clues from the Kashmir Himalaya

Journal of Plant Ecology ◽

10.1093/jpe/rtr021 ◽

2011 ◽

Vol 5 (2) ◽

pp. 167-173 ◽

Cited By ~ 15

Author(s):

M. A. Shah ◽

Z. A. Reshi ◽

C. Lavoie

Keyword(s):

Range Size ◽

Kashmir Himalaya ◽

Native Range ◽

Plant Invasiveness

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Time since first record and population density influence range sizes of non-native plants, but also of native plants, in a chronically overgrazed island

Plant Ecology and Evolution ◽

10.5091/plecevo.2021.1806 ◽

2021 ◽

Vol 154 (2) ◽

pp. 173-182

Author(s):

Pedro P. Garcillán ◽

Carlos Martorell

Keyword(s):

Population Density ◽

Residence Time ◽

Native Species ◽

Native Plants ◽

Range Size ◽

Time Range ◽

Mexican Pacific ◽

Size Relationship ◽

Relationship Of ◽

The Relationship

Background and aims − Humans are increasingly introducing species to new regions. It is necessary to understand the processes that drive the expansion of non-native species into these new habitats across multiple spatiotemporal scales.Material and methods − We studied the spatial distribution of the non-native flora (39 species) of Guadalupe Island (246 km2) in the Mexican Pacific. We analyzed how residence time (time since first report in historical sources, 1875–2004) and species attributes (population density, flowering phenology, and individual height) are related with range sizes of non-native plants. To test whether the residence time – range size relationship of non-native plants can result from other factors besides time since their arrival, we compared it to the residence time – range size relationship of native plants. Range sizes were obtained using herbarium data and a systematic field sampling of 110 transects (50 × 2 m) throughout the entire island. We used beta regression to analyze the relationship of range sizes with residence time and species attributes.Key results − Range sizes of non-natives showed a positive relationship with residence time, flower phenology, and notably with plant density, but not with individual height. However, similar relationships were found for native species, casting doubts on whether our results reflect the range expansion rates of non-native species. Conclusions − Our results suggest that the production of large numbers of propagules, both as a result of long reproductive periods and large population sizes, determines to a large extent the rates of range size expansion of non-native species. However, the relationship we found between time since discovery and range size may arise from sampling biases, biological processes, or – most likely – both. This highlights the need for new approaches that allow us to discern the relative contributions of bias and process in our study of non-native species expansion.

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Controls on pathogen species richness in plants’ introduced and native ranges: roles of residence time, range size and host traits

Ecology Letters ◽

10.1111/j.1461-0248.2010.01543.x ◽

2010 ◽

Vol 13 (12) ◽

pp. 1525-1535 ◽

Cited By ~ 104

Author(s):

Charles E. Mitchell ◽

Dana Blumenthal ◽

Vojtěch Jarošík ◽

Emily E. Puckett ◽

Petr Pyšek

Keyword(s):

Species Richness ◽

Residence Time ◽

Range Size ◽

Time Range

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Native range size and growth form in Cactaceae predict invasiveness and impact

NeoBiota ◽

10.3897/neobiota.30.7253 ◽

2016 ◽

Vol 30 ◽

pp. 75-90 ◽

Cited By ~ 20

Author(s):

Ana Novoa ◽

Sabrina Kumschick ◽

David M. Richardson ◽

Mathieu Rouget ◽

John R.U. Wilson

Keyword(s):

Growth Form ◽

Range Size ◽

Native Range

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Genome Size Variation Between the Native and Invasive Ranges of Senecio madagascariensis (Asteraceae)

Systematic Botany ◽

10.1600/036364420x15801369352487 ◽

2020 ◽

Vol 45 (1) ◽

pp. 212-218

Author(s):

Bruno Dematteis ◽

María S. Ferrucci ◽

Pablo Ortega-Baes ◽

Juan P. Coulleri

Keyword(s):

Invasive Species ◽

Genome Size ◽

Ploidy Level ◽

Native Species ◽

Size Variation ◽

Published Data ◽

Native Range ◽

Genome Size Variation ◽

Invasive Range ◽

Bioclimatic Variables

Abstract—Invasive species must colonize new habitats away from their native range; therefore, factors affecting plant dispersal play a key role in invasion. The ploidy level and genome size (or Cx value) can affect the dispersal traits, physiology, and ecology of invasive species over a few generations, generating individuals that can face fluctuating environments, exploit new ones, and compete with native species. Several studies have demonstrated that invasive species tend to have smaller genomes than their noninvasive congeners, which is explained by the role that the Cx value plays in phenotypic evolution and ecological tolerance. In order to test this hypothesis, we compare the genome size variation in Argentine populations (invasive range) vs. South African populations (native range) of S. madagascariensis. To meet our goals, we estimated the Cx value of invasive populations collected on field trips, while for native populations we considered available published data. We extracted the bioclimatic variables in order to establish the ecological amplitude in which the genome sizes may be distributed. Our results evidenced larger genomes in the invasive range than in the native one. Furthermore, we propose that large genomes of the invasive populations could be mainly explained by the founder genotypes effect and the anthropogenic introduction of this species to Argentina. In addition, we demonstrated that genotypes with big genomes can tolerate different environmental conditions from those of their native range. Therefore, they could present a greater ability for colonizing new environments. The implications and importance of ploidy level in the invasion of S. madagascariensis are discussed.

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