Are rare plant species less resistant than common ones to herbivores? A multi‐plant species study using above‐ and below‐ground generalist herbivores

Bürli, Sarah; Ensslin, Andreas; Kempel, Anne; Fischer, Markus

doi:10.1002/ece3.10482

Cited by 1 publication

(1 citation statement)

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“…Gorman et al (2014) also found that insect herbivory was lower, and the composition of insect communities were different on endemics relative to nonendemics. Consequently, the lower biomass of rare plant species may reflect trade-offs with other functional traits and ecological processes, such as increased morphological complexity (Gurevich & Hadany, 2021), enhanced pollinator dynamics (Benadi & Gegear, 2018), and reduced insect herbivory (Bürli et al, 2023;Gorman et al, 2014). et al (2019), biomass and biomass partitioning are critical drivers of trade-offs between plant traits and strategies.…”

Section: Discussionmentioning

confidence: 99%

An evolutionary case for plant rarity: Eucalyptus as a model system

Nytko,

Senior,

Wooliver

et al. 2024

Ecology and Evolution

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Species rarity is a common phenomenon across global ecosystems that is becoming increasingly more common under climate change. Although species rarity is often considered to be a stochastic response to environmental and ecological constraints, we examined the hypothesis that plant rarity is a consequence of natural selection acting on performance traits that affect a species range size, habitat specificity, and population aggregation; three primary descriptors of rarity. Using a common garden of 25 species of Tasmanian Eucalyptus, we find that the rarest species have 70% lower biomass than common species. Although rare species demonstrate lower biomass, rare species allocated proportionally more biomass aboveground than common species. There is also a negative phylogenetic autocorrelation underlying the biomass of rare and common species, indicating that traits associated with rarity have diverged within subgenera as a result of environmental factors to reach different associated optima. In support of our hypothesis, we found significant positive relationships between species biomass, range size and habitat specificity, but not population aggregation. These results demonstrate repeated convergent evolution of the trait‐based determinants of rarity across the phylogeny in Tasmanian eucalypts. Furthermore, the phylogenetically driven patterns in biomass and biomass allocation seen in rare species may be representative of a larger plant strategy, not yet considered, but offering a mechanism as to how rare species continue to persist despite inherent constraints of small, specialized ranges and populations. These results suggest that if rarity can evolve and is related to plant traits such as biomass, rather than a random outcome of environmental constraints, we may need to revise conservation efforts in these and other rare species to reconsider the abiotic and biotic factors that underlie the distributions of rare plant species.

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