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Ecology of supralittoral lichens on Hong Kong rocky shoresChu, Fung, Joanna., 朱鳳. January 1997 (has links)
published_or_final_version / Ecology and Biodiversity / Doctoral / Doctor of Philosophy
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Occurrence and properties of the multicopper oxidases laccase and tyrosinase in lichens.Laufer, Zsanett. 06 November 2013 (has links)
The work presented in this thesis describes the occurrence and properties of two multicopper oxidases derived from lichens. Despite numerous data on laccases and tyrosinases in fungi and flowering plants, this is the first report of the occurrence of these enzymes in lichenized ascomycetes. Extracellular laccase and tyrosinase activity was measured in 50 species of lichens from different taxonomic groupings and contrasting habitats. Out of 27 species tested from suborder Peltigerineae, all displayed laccase and tyrosinase activity that correlated to each other, while activity was absent in species tested from other lichen groups. Identification of the enzymes as laccases and tyrosinases was confirmed by the ability of lichen thalli or leachates to readily metabolize substrates such as 2,2’-azino(bis-3-ethylbenzthiazoline-6-sulfonate) (ABTS), syringaldazine and o-tolidine in case of laccase and L-dihydroxyphenylalanine (L-DOPA), Ltyrosine
and epinephrine in case of tyrosinase in the absence of hydrogen peroxide. The activities of both enzymes were highly sensitive to cyanide and azide, and tyrosinase activity was sensitive to hexylresorcinol. Laccase activity had typical pH and temperature optima and an absorption spectrum with a peak at 614 nm. Tyrosinases could be activated by sodium dodecyl
sulphate (SDS) and had typical tyrosinase molecular masses of approx. 60 kDa. The diversity of laccase isoforms in 20 lichen species from suborder Peltigerineae was investigated. The molecular masses of the active forms of most laccases varied between 135 and 190 kDa, although some lichens within the family Peltigeraceae had laccases with higher masses, typically varying from 200 to over 350 kDa. Most species contained one oligomeric laccase isoform. Desiccation and wounding stimulated laccase activity, while only wounding stimulated tyrosinase activity. The ability of laccases to decolorize dye is a classic attribute of laccases, and one with biotechnological potential. The ability of eight lichen species to decolourize different types of dyes was therefore tested. Interestingly, results showed that not only species belonging to suborder Peltigerineae but also species from other lichen group effectively decolourised dyes after 48 h suggesting that other oxidases appear to have ability to decolorize. Hopefully, our
work could contribute to the better knowledge and application of lichen multicopper oxidases. / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2012.
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Lichen response to the environment and forest structure in the western Cascades of OregonMartin, Erin P. 30 June 2005 (has links)
Lichens are an important part of the biota in western Oregon forests, where
they perform valuable ecological roles and contribute significantly to biodiversity.
Lichens in western Oregon are threatened by a number of factors including air
pollution and land use practices. If we wish to maintain the persistence of lichens in
future landscapes it is critical that we understand the responses of lichen communities
and individual lichen species to the environment and forest structure. This dissertation
explores factors that are related to differences in lichen community composition and
the distributions of individual lichen species in the western Cascades of Oregon, using
a large landscape scale data set. I sought to relate major gradients in lichen
community composition to environmental factors, and describe differences in lichen
communities with respect to forest age (Chapter 2). I found three major gradients in
lichen communities at a landscape scale in the western Oregon Cascades. These
gradients were related to climate as expressed by elevation and annual temperature, air
quality, north-south position, the richness of epiphytic macrolichens, and forest age. I developed a rarity score, which can be used to identify hotspots of rare species
diversity at a landscape scale (Chapter 3). I then built descriptive models of this rarity
score to identify abiotic and biotic factors associated with the occurrence of rarity
hotspots. I found that models of rarity score that used explanatory variables based on
lichen community composition performed better than models that used explanatory
variables based solely on environmental factors. I narrowed my focus to the level of
individual species responses to the environment and forest structure by developing
habitat models for 11 lichen species in the western Cascades (Chapter 4). We selected
these species because they performed important ecological roles, were rare across the
landscape and associated with old growth forests, or because their distributions were
poorly understood. These models can be used to increase the efficiency of landscape
level surveys for rare species, predict the response of these species to forest
management practices, and understand factors associated with the distributions of
these lichens. / Graduation date: 2006
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