Lichen endozoochory by snails - PubMed (original) (raw)
Lichen endozoochory by snails
Steffen Boch et al. PLoS One. 2011.
Abstract
Endozoochory plays a prominent role for the dispersal of seed plants. However, for most other plant taxa it is not known whether this mode of dispersal occurs at all. Among those other taxa, lichens as symbiotic associations of algae and fungi are peculiar as their successful dispersal requires movement of propagules that leaves the symbiosis functional. However, the potential for endozoochorous dispersal of lichen fragments has been completely overlooked. We fed sterile thalli of two foliose lichen species (Lobaria pulmonaria and Physcia adscendens) differing in habitat and air-quality requirements to nine snail species common in temperate Europe. We demonstrated morphologically that L. pulmonaria regenerated from 29.0% of all 379 fecal pellets, whereas P. adscendens regenerated from 40.9% of all 433 fecal pellets, showing that lichen fragments survived gut passage of all snail species. Moreover, molecular analysis of regenerated lichens confirmed the species identity for a subset of samples. Regeneration rates were higher for the generalist lichen species P. adscendens than for the specialist lichen species L. pulmonaria. Furthermore, lichen regeneration rates varied among snail species with higher rates after gut passage of heavier snail species. We suggest that gastropods generally grazing on lichen communities are important, but so far completely overlooked, as vectors for lichen dispersal. This opens new ecological perspectives and questions the traditional view of an entirely antagonistic relationship between gastropods and lichens.
Conflict of interest statement
Competing Interests: The authors have declared that no competing interests exist.
Figures
Figure 1. Microscope images of lichen species regenerated from snail feces.
A) I: isidioid soredia of L. pulmonaria. B) S: squamule (shell-formed thallus piece), and C: cilium (thread-like appendage) of P. adscendens.
Figure 2. Variation in regeneration rate of lichen species from fecal pellets of snail species (means +s.e.m).
Snail species are sorted from smallest to largest body mass.
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References
- Fuentes M. Frugivory, seed dispersal and plant community ecology. Trends Ecol Evol. 2000;15:487–488.
- Duthie C, Gibbs G, Burns KC. Seed Dispersal by Weta. Science. 2006;311:1575. - PubMed
- Türke M, Heinze E, Andreas K, Svendsen SM, Gossner MM, et al. Seed consumption and dispersal in ant-dispersed plants by slugs. Oecologia. 2010;163:681–693. - PubMed
- Lutzoni F, Miadlikowska J. Lichens. Current Biology. 2009;19:R502–R503. - PubMed
- Seaward MRD. Environmental role of lichens. In: Nash TH III, editor. Lichen Biology. Cambridge: Cambridge Univ. Press, Ed. 2; 2008. pp. 274–298.
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