Hagenbo, Andreas
- Department of Forest Mycology and Plant Pathology, Swedish University of Agricultural Sciences
Research article2017Peer reviewedOpen access
Hagenbo, Andreas; Clemmensen, Karina E.; Finlay, Roger D.; Kyaschenko, Julia; Lindahl, Bjoern D.; Fransson, Petra; Ekblad, Alf
In boreal forest soils, ectomycorrhizal fungi are fundamentally important for carbon (C) dynamics and nutrient cycling. Although their extraradical mycelium (ERM) is pivotal for processes such as soil organic matter build-up and nitrogen cycling, very little is known about its dynamics and regulation.
In this study, we quantified ERM production and turnover, and examined how these two processes together regulated standing ERM biomass in seven sites forming a chronosequence of 12- to 100-yr-old managed Pinus sylvestris forests. This was done by determining ERM biomass, using ergosterol as a proxy, in sequentially harvested in-growth mesh bags and by applying mathematical models.
Although ERM production declined with increasing forest age from 1.2 to 0.5 kg ha1 d1, the standing biomass increased from 50 to 112 kg ha1. This was explained by a drastic decline in mycelial turnover from seven times to one time per year with increasing forest age, corresponding to mean residence times from 25 d up to 1 yr.
Our results demonstrate that ERM turnover is the main factor regulating biomass across differently aged forest stands. Explicit inclusion of ERM parameters in forest ecosystem C models may significantly improve their capacity to predict responses of mycorrhiza-mediated processes to management and environmental changes.
chronosequence; ectomycorrhiza; ergosterol; extramatrical mycelium; extraradical mycelium; fungal biomass; production; turnover
New Phytologist
2017, Volume: 214, number: 1, pages: 424-431
SLU Plant Protection Network
Microbiology
Ecology
Environmental Sciences
DOI: https://doi.org/10.1111/nph.14379
https://res.slu.se/id/publ/80780