Epiphyte diversity on Scottish aspen – a component of the extended phenotype
dc.contributor.advisor
Ennos, Richard
en
dc.contributor.advisor
Iason, Glenn
en
dc.contributor.advisor
Ellis, Chris
en
dc.contributor.author
Davies, Chantel
en
dc.contributor.sponsor
Biotechnology and Biological Sciences Research Council (BBSRC)
en
dc.date.accessioned
2012-08-07T13:52:39Z
dc.date.available
2012-08-07T13:52:39Z
dc.date.issued
2012-06-22
dc.description.abstract
Species interactions are recognised as an important evolutionary process, with
foundation species in particular being of exceptional importance. Foundation species
are those species exhibiting dynamic physical traits, under strong genetic control,
that shape the natural processes of habitats and ecosystems. These traits lead to
extended consequences for the associated organisms in their community. Therefore,
intra-specific variation of a foundation species can have important evolutionary
consequences for habitats, communities and entire ecosystems.
One such foundation species is aspen (Populus tremula L.), which has important
conservation value, particularly for the high diversity of associated species. In
Scotland aspen exists in fragmented clonal patches, but has been found to contain a
high diversity of associated organisms some of which have a UK Biodiversity Action
Plan (BAP). One such group of organisms of high diversity and conservation value
in Scotland are the epiphytic cryptogams (i.e. mosses, liverworts, lichens). To date
more than 300 species have been recorded on aspen in Scotland, comprising
approximately 40% of the epiphyte flora of Europe.
The research presented here uses a combination of natural aspen system and two
aspen common gardens to test the effects of aspen genetic diversity on physical traits
potentially important for epiphyte diversity. The traits investigated were bark texture
and bark phenolic chemistry. Bark texture in the wild clones was found vary
significantly between clones and under strong genetic control (up to 40%). Bark
phenolic chemistry also showed significant genotypic variation, but could not be
correlated with patterns of epiphyte species richness and diversity. Nevertheless,
epiphytes showed significant patterns related to aspen genotype, particularly along a
gradient of bark texture. The results indicate that epiphyte communities are part of
the ‘extended phenotype’ of native aspen populations in Scotland are very important
for maintaining current levels of epiphyte diversity. A greater diversity and
abundance of aspen genotypes in the landscape are essential for increasing epiphyte
species richness and diversity, and for ecosystem health as a whole.
en
dc.identifier.uri
http://hdl.handle.net/1842/6211
dc.language.iso
en
dc.publisher
The University of Edinburgh
en
dc.relation.hasversion
Milne, R. I., Davies, C., Prickett, R., Inns, L. H., Chamberlain, D. F. (2010). Phylogeny of Rhododendron subgenus Hymenanthes based on chloroplast DNA markers: between-lineage hybridisation during adaptive radiation? Plant Systematics and Evolution 285(3-4): 233-244
en
dc.subject
Populus tremula
en
dc.subject
aspen
en
dc.subject
lichens
en
dc.subject
diversity
en
dc.subject
epiphyte
en
dc.title
Epiphyte diversity on Scottish aspen – a component of the extended phenotype
en
dc.type
Thesis or Dissertation
en
dc.type.qualificationlevel
Doctoral
en
dc.type.qualificationname
PhD Doctor of Philosophy
en
Files
Original bundle
This item appears in the following Collection(s)