Soil chemical properties, rather than landscape context, influence woodland fungal communities along an urban‐rural gradient
Identifieur interne : 000085 ( Main/Exploration ); précédent : 000084; suivant : 000086Soil chemical properties, rather than landscape context, influence woodland fungal communities along an urban‐rural gradient
Auteurs : Mark Newbound [Australie] ; Lauren T. Bennett [Australie] ; Josquin Tibbits [Australie] ; Sabine Kasel [Australie]Source :
- Austral Ecology [ 1442-9985 ] ; 2012-04.
English descriptors
- Entity :
- org : ARCUE, Agencourt Bioscience Corporation, Australia Abstract With, Australia Soil, Australian Research Centre for Urban Ecology, Australian Research Centre for Urban Ecology, Royal Botanic Gardens Melbourne, Beckman Coulter Inc, DRNE, DSE, DSNR, Department of Forest and Ecosystem, Department of Primary Industries, Victorian, E Ltd, Plymouth, UK, Holsworth Wildlife Research Fund, Mo Bio Laboratories Inc., National Herbarium of Victoria, SAS Institute Inc, Soil Survey Staff, University of Melbourne.
- pers : A. Hahs, M. McDonnell, M. Newbound, Phoenix, Society.
- place : Australia, Beverly, CA, Carlsbad, Eppendorf, Europe, Finland, Fullerton, Hanover, Lodz, MA, MD, Melbourne, Montpellier, Poland, Sweden, Tokyo.
- Teeft :
- Aerial photograph, Agencourt bioscience corporation, Agricultural landscape, Alui, Atmospheric deposition, Author journal compilation, Available phosphorus, Background level, Bennett, Best combination, Bioenv, Bioenv analysis, Biol, Boreal forest, Canopy, Canopy openness, Central business district, Chemical property, Clear separation, Community composition, Composite sample, Correlated, Datum, Datum analysis, Dickie fitzjohn, Dominant land, Ecol, Ecological, Ecological society, Ecology, Ecosystem, Ecosystem function, Ecosystem process, Ecosystem science, Ecosystem study, Ectomycorrhizal, Ectomycorrhizal fungus, Electrical conductivity, Eucalyptus, Eucalyptus camaldulensis, Fruiting, Fruiting body, Fruiting body datum, Functional group, Fungal, Fungal community, Fungal community composition, Fungal diversity, Fungus, Gardes bruns, Global bioenv, Government printing office, Hahs, Hahs mcdonnell, Individual enzyme, Landscape context, Landscape shape index, Landscape variable, Light analyzer, Melbourne, More important, Mycorrhizal, Mycorrhizal fungus, Mycorrhizal specie, Natural gradient, Newbound, Nitrogen availability, Nmds ordination, Nutrient, Ochimaru fukuda, Openness, Ordination, Ordination stress value, Other research, Particle size distribution, Past land, Past practice, Pearson correlation coefficient, Permutation, Permutation test, Phosphorus, Physical information, Physicochemical, Plant soil, Polymorphism, Population association, Primer, Primer version, Principal component analysis, Rank correlation, Remnant, Remnant vegetation, Remnant vegetation patch, Remnant woodland, Reproducible trf, Restriction enzyme, Result show, Same reserve, Saprotrophic, Saprotrophic fungus, Saprotrophs, Significant correlation, Soil biol, Soil chemical property, Soil core, Soil disturbance, Soil eutrophication, Soil fungal community composition, Soil physicochemical property, Soil physicochemical variable, Soil property, Soil survey staff, Soil texture, Soil variable, Spearman rank correlation coefficient, Specie, Sporocarp, Sporocarp collection, Sporocarp datum, Sporocarp survey, Standardized unitless measure, Statistical significance, Study site, Temperate grassy woodland, Terminal restriction fragment length polymorphism, Total variance, Tree canopy, Trf, Urban area, Urban ecology, Urban land, Urban landscape, Urban plan, Urban pollution gradient, Urban remnant, Urban site, Urban soil, Urbanization, Urbanization gradient, User manual, Vegetation, Wallenda kottke, Woodland.
Abstract
With the expansion of cities around the world there is a growing interest in the factors that influence biodiversity and ecosystem processes in urban areas. Fungi are exceptionally diverse and play key roles in ecosystem function, yet despite predictions of negative impacts due to urbanization, fungi have been generally overlooked in urban ecological studies. We surveyed fungi in 16 remnant river red gum (Eucalyptus camaldulensis: Myrtaceae) woodlands along a gradient of 4–35 km from the city of Melbourne (south‐east Australia). Using both sporocarp surveys and terminal restriction fragment length polymorphism (T‐RFLP; primer pair ITS1‐F‐ITS4), we examined relationships between fungal community composition, landscape context (i.e. urbanization) and soil physicochemical properties. Community compositions from sporocarp data were significantly correlated with those from T‐RFLP data, largely because of correlations with ectomycorrhizal sporocarps (Spearman rank correlation coefficients ρ 0.31–0.42) rather than saprotrophic fungi (ρ 0.18–0.21). Principal components analysis of soil properties and non‐metric multidimensional scaling ordinations of fungal community composition showed no clear separation of sites according to urbanization, and there were no significant correlations between fungal community composition and urbanization. However, fungal community composition was significantly correlated with soil chemical properties (ρ 0.41–0.55). These data suggest that site‐scale soil properties, and associated effects of past and current land management activities, were more important in determining fungal community composition than the landscape‐level influences of urbanization.
Url:
DOI: 10.1111/j.1442-9993.2011.02269.x
Affiliations:
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Hahs</term><term>M. McDonnell</term><term>M. Newbound</term><term>Phoenix</term><term>Society</term></keywords><keywords scheme="Entity" type="place" xml:lang="en"><term>Australia</term><term>Beverly</term><term>CA</term><term>Carlsbad</term><term>Eppendorf</term><term>Europe</term><term>Finland</term><term>Fullerton</term><term>Hanover</term><term>Lodz</term><term>MA</term><term>MD</term><term>Melbourne</term><term>Montpellier</term><term>Poland</term><term>Sweden</term><term>Tokyo</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Aerial photograph</term><term>Agencourt bioscience corporation</term><term>Agricultural landscape</term><term>Alui</term><term>Atmospheric deposition</term><term>Author journal compilation</term><term>Available phosphorus</term><term>Background level</term><term>Bennett</term><term>Best combination</term><term>Bioenv</term><term>Bioenv analysis</term><term>Biol</term><term>Boreal forest</term><term>Canopy</term><term>Canopy openness</term><term>Central business district</term><term>Chemical property</term><term>Clear separation</term><term>Community composition</term><term>Composite sample</term><term>Correlated</term><term>Datum</term><term>Datum analysis</term><term>Dickie fitzjohn</term><term>Dominant land</term><term>Ecol</term><term>Ecological</term><term>Ecological society</term><term>Ecology</term><term>Ecosystem</term><term>Ecosystem function</term><term>Ecosystem process</term><term>Ecosystem science</term><term>Ecosystem study</term><term>Ectomycorrhizal</term><term>Ectomycorrhizal fungus</term><term>Electrical conductivity</term><term>Eucalyptus</term><term>Eucalyptus camaldulensis</term><term>Fruiting</term><term>Fruiting body</term><term>Fruiting body datum</term><term>Functional group</term><term>Fungal</term><term>Fungal community</term><term>Fungal community composition</term><term>Fungal diversity</term><term>Fungus</term><term>Gardes bruns</term><term>Global bioenv</term><term>Government printing office</term><term>Hahs</term><term>Hahs mcdonnell</term><term>Individual enzyme</term><term>Landscape context</term><term>Landscape shape index</term><term>Landscape variable</term><term>Light analyzer</term><term>Melbourne</term><term>More important</term><term>Mycorrhizal</term><term>Mycorrhizal fungus</term><term>Mycorrhizal specie</term><term>Natural gradient</term><term>Newbound</term><term>Nitrogen availability</term><term>Nmds ordination</term><term>Nutrient</term><term>Ochimaru fukuda</term><term>Openness</term><term>Ordination</term><term>Ordination stress value</term><term>Other research</term><term>Particle size distribution</term><term>Past land</term><term>Past practice</term><term>Pearson correlation coefficient</term><term>Permutation</term><term>Permutation test</term><term>Phosphorus</term><term>Physical information</term><term>Physicochemical</term><term>Plant soil</term><term>Polymorphism</term><term>Population association</term><term>Primer</term><term>Primer version</term><term>Principal component analysis</term><term>Rank correlation</term><term>Remnant</term><term>Remnant vegetation</term><term>Remnant vegetation patch</term><term>Remnant woodland</term><term>Reproducible trf</term><term>Restriction enzyme</term><term>Result show</term><term>Same reserve</term><term>Saprotrophic</term><term>Saprotrophic fungus</term><term>Saprotrophs</term><term>Significant correlation</term><term>Soil biol</term><term>Soil chemical property</term><term>Soil core</term><term>Soil disturbance</term><term>Soil eutrophication</term><term>Soil fungal community composition</term><term>Soil physicochemical property</term><term>Soil physicochemical variable</term><term>Soil property</term><term>Soil survey staff</term><term>Soil texture</term><term>Soil variable</term><term>Spearman rank correlation coefficient</term><term>Specie</term><term>Sporocarp</term><term>Sporocarp collection</term><term>Sporocarp datum</term><term>Sporocarp survey</term><term>Standardized unitless measure</term><term>Statistical significance</term><term>Study site</term><term>Temperate grassy woodland</term><term>Terminal restriction fragment length polymorphism</term><term>Total variance</term><term>Tree canopy</term><term>Trf</term><term>Urban area</term><term>Urban ecology</term><term>Urban land</term><term>Urban landscape</term><term>Urban plan</term><term>Urban pollution gradient</term><term>Urban remnant</term><term>Urban site</term><term>Urban soil</term><term>Urbanization</term><term>Urbanization gradient</term><term>User manual</term><term>Vegetation</term><term>Wallenda kottke</term><term>Woodland</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">With the expansion of cities around the world there is a growing interest in the factors that influence biodiversity and ecosystem processes in urban areas. Fungi are exceptionally diverse and play key roles in ecosystem function, yet despite predictions of negative impacts due to urbanization, fungi have been generally overlooked in urban ecological studies. We surveyed fungi in 16 remnant river red gum (Eucalyptus camaldulensis: Myrtaceae) woodlands along a gradient of 4–35 km from the city of Melbourne (south‐east Australia). Using both sporocarp surveys and terminal restriction fragment length polymorphism (T‐RFLP; primer pair ITS1‐F‐ITS4), we examined relationships between fungal community composition, landscape context (i.e. urbanization) and soil physicochemical properties. Community compositions from sporocarp data were significantly correlated with those from T‐RFLP data, largely because of correlations with ectomycorrhizal sporocarps (Spearman rank correlation coefficients ρ 0.31–0.42) rather than saprotrophic fungi (ρ 0.18–0.21). Principal components analysis of soil properties and non‐metric multidimensional scaling ordinations of fungal community composition showed no clear separation of sites according to urbanization, and there were no significant correlations between fungal community composition and urbanization. However, fungal community composition was significantly correlated with soil chemical properties (ρ 0.41–0.55). These data suggest that site‐scale soil properties, and associated effects of past and current land management activities, were more important in determining fungal community composition than the landscape‐level influences of urbanization.</div></front></TEI><affiliations><list><country><li>Australie</li></country><region><li>Victoria (État)</li></region><settlement><li>Melbourne</li></settlement><orgName><li>Université de Melbourne</li></orgName></list><tree><country name="Australie"><region name="Victoria (État)"><name sortKey="Newbound, Mark" sort="Newbound, Mark" uniqKey="Newbound M" first="Mark" last="Newbound">Mark Newbound</name></region><name sortKey="Bennett, Lauren T" sort="Bennett, Lauren T" uniqKey="Bennett L" first="Lauren T." last="Bennett">Lauren T. Bennett</name><name sortKey="Kasel, Sabine" sort="Kasel, Sabine" uniqKey="Kasel S" first="Sabine" last="Kasel">Sabine Kasel</name><name sortKey="Newbound, Mark" sort="Newbound, Mark" uniqKey="Newbound M" first="Mark" last="Newbound">Mark Newbound</name><name sortKey="Newbound, Mark" sort="Newbound, Mark" uniqKey="Newbound M" first="Mark" last="Newbound">Mark Newbound</name><name sortKey="Tibbits, Josquin" sort="Tibbits, Josquin" uniqKey="Tibbits J" first="Josquin" last="Tibbits">Josquin Tibbits</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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