Microbial Community Structure of Soils under Four Productivity Classes of Aspen Forests in Northern British Columbia

Trembling aspen (Populus tremuloides) is widely distributed in North American forests. Increased stand productivity with resource availability has been reported, but the relationship between soil microbial community structure and stand productivity remains unclear. To examine soil microbial composit...

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Published inÉcoscience (Sainte-Foy) Vol. 20; no. 3; pp. 264 - 275
Main Authors Fox, Mark D., Tackaberry, Linda E., Drouin, Pascal, Bergeron, Yves, Bradley, Robert, Massicotte, Hugues B., Chen, Han Y.H.
Format Journal Article
LanguageEnglish
Published Université Laval 01.09.2013
Université Laval
Taylor & Francis
Subjects
aspen
biodiversity
biodiversité
biomass
biomasse
communautés microbiennes
community structure
correspondence analysis
ectomycorrhizae
forests
fungi
microbial biomass
microbial communities
mycorhize
mycorrhiza
peuplier faux-tremble
Populus tremuloides
soil bacteria
soil fertility
soil properties
stand structure
trees
British Columbia
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Summary:Trembling aspen (Populus tremuloides) is widely distributed in North American forests. Increased stand productivity with resource availability has been reported, but the relationship between soil microbial community structure and stand productivity remains unclear. To examine soil microbial composition of 4 aspen stand productivity classes, we assessed soil properties, microbial biomass and respiration, and bacterial and ectomycorrhizal diversity. Most variables showed no significant differences between productivity classes. However, mean values for basal respiration (0.05 to 27.99 µg CO2-C·g-1 soil·h-1), bacterial biomass, and metabolic quotient (0.08 to 5.22 CO2-C·mg-1 Cmic·h-1) were lowest in low productivity (Class 1) sites. Bacteria to fungi ratios were significantly lower (P = 0.05) in Class 1 compared to other classes. Microbial biomass ranged from 1.39 to 8.11 mg Cmic·g-1 soil. Thirty-seven distinct aspen ectomycorrhizas (ECM) were characterized, 21 were considered rare (from ≤3 trees). ECM richness did not differ significantly between classes, although relative abundance for some types did. Canonical correspondence analysis showed productivity class explained most microbial community variation, e.g., ECM fungi (80% explained) and soil bacteria (46%). Despite some differences, we could not identify statistically significant bacterial or ECM assemblages linked to stand productivity. Results may reflect a strong association between microbial processes and the dominant host, aspen. Aspen associated with widely distributed fungi common to all classes, possibly facilitating its survival and growth, including on sites exhibiting low pH and low soil fertility.
Bibliography:http://dx.doi.org/10.2980%2F20-3-3611
ISSN:1195-6860
2376-7626
DOI:10.2980/20-3-3611