Overview: Our currently FSP funded research is showing that linkage into a common mycorrhizal network (CMN) with residual trees is important to the establishment of Douglas-fir seedlings in the interior dry Douglas-fir forests. A CMN is an underground network of genetically compatible mycorrhizal fungi linking roots of trees of the same or different species. The CMN associated with residual trees in cutover or burned areas appears to facilitate new regeneration by providing mycorrhizal inoculum, carbon, and water from the mature trees. This project examines the spatial extent and genetic structure of common mycorrhizal networks (CMNs) in dry Douglas-fir forests. The information derived from this project will apply directly to the sustainability program, under the theme of ecosystem structure, function and processes, and biodiversity related to forest management (theme 1), the topic of effectiveness of stand level structures in maintaining biodiversity (topic 1.4), priority c (appropriate targets and configurations of stand level structures in dry forests for maintaining biodiversity). Specifically, We are characterizing the spatial extent, structure, and genetics of common mycorrhizal networks linking overstory Douglas-fir trees with understory cohorts in mature and old-growth forests in the Interior Douglas-fir zone. This information will be used to determine target sizes and configurations of green tree patches that should be retained following disturbance (e.g., partial cutting, salvage logging following wildfire) in order to conserve the ability of the ecosystems to regenerate and hence develop into healthy stand structures. We will contrast CMNs between two soil moisture regimes within the dry, cool biogeoclimatic subzone (IDFdk) of southern interior British Columbia for three: (1) to provide site series specific guidelines; (2) to test whether the importance of CMN facilitation increases with site water stress, and (3) to use soil moisture regime as a proxy for changes in site water stress and regeneration potential with climate change. Background: Tree establishment and growth, and hence ecosystem productivity, are largely influenced by the ectomycorrhizal colonization of tree roots. Of particular importance is the potential for fungal mycelia to link the roots of individual trees to other trees or new regeneration, acting as conduits for the exchange of water, carbon and nutrients. The transfer of C, N, and P between mycorrhizal plants has been demonstrated in the field (Smith & Read 1997; Simard et al. 2002; Leake et al. 2004; Simard & Durall 2004), including net C transfer from Betula papyrifera to P. menziesii trees in ICH forests (Simard et al. 1997a; Simard et al. 1997b). Our recent FSP funded work has demonstrated that linkage into a CMN with residual trees improves the survivability and productivity of naturally and artificially regenerated Douglas-fir seedlings, and hence is important in stand establishment following disturbance. A newly initiated FSP project is also examining how the importance of this CMN facilitation changes with increasing regional drought associated with climate change. In this project, we will use contemporary tools in molecular genomics to distinguish between individual genotypes of fungi and tree roots (Saari et al. 2005), allowing quantitative and qualitative examination of CMNs among trees and understory regeneration in multi-cohort Douglas-fir forest stands. The importance of Interior Douglas-fir [P. menziesii var. glauca (Beissn.) Franco] forests to British Columbia?s economy and ecosystems are well understood, yet associations between forest dynamics and belowground ecology are not. Moisture deficits common to these forests make them particularly vulnerable to ecological stresses associated with climate change, wildfires, and outbreaks of insects and disease. Conserving or strengthening functional links between tree generations could help mediate this stress and bolster resilie ...
Simard, Suzanne W.. 2008. Determining stand level structures in dry Douglas-fir forests that maintain appropriate levels of ectomycorrhizal genetic diversity to facilitate Douglas-fir regeneration. Forest Investment Account (FIA) - Forest Science Program. Forest Investment Account Report. FIA2008MR163
Topic: FLNRORD Research Program
Keywords: Forest, Investment, Account, (FIA), British, Columbia
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