Carbon Dioxide and Methane Formation in Norway Spruce Stems Infected by White-Rot Fungi

Ari Hietala,Halvor Solheim,Harald Kvaalen,Peter Dörsch

doi:10.3390/f6093304

Ari Hietala, Halvor Solheim + Show 2 more

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https://doi.org/10.3390/f6093304

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Abstract

Globally, billions of tons of carbon sequestered in trees are annually recycled back to the atmosphere through wood decomposition by microbes. In Norway, every fifth Norway spruce shows at final harvest infection by pathogenic white-rot fungi in the genera Heterobasidion and Armillaria. As these fungi can mineralize all components of wood, we predicted that they have a significant carbon footprint. Gas samples taken from infected stems were analyzed for CO2 and CH4 concentrations, and wood samples from different parts of the decay columns were incubated under hypoxic (4% O2) and anoxic laboratory conditions. In spring and summer the stem concentrations of CO2 were generally two times higher in trees with heartwood decay than in healthy trees. For most of the healthy trees and trees with heartwood decay, mean stem concentrations of CH4 were comparable to ambient air, and only some Armillaria infected trees showed moderately elevated CH4. Consistently, low CH4 production potentials were recorded in the laboratory experiment. Up-scaling of CO2 efflux due to wood decay in living trees suggests that the balance between carbon sequestration and emission may be substantially influenced in stands with high frequency of advanced root and stem heartwood decay.

Highlights

The global carbon cycle involves exchange of carbon between the atmosphere and marine and terrestrial biospheres, and sediments that include fossil fuels
For most of the healthy trees and trees with heartwood decay, mean stem concentrations of CH4 were comparable to ambient air (~2 ppm)
For trees infected by Heterobasidion annosum s.l. and Armillaria species, the most common white-rot fungi associated with heartwood of Norway spruce in boreal forests, the stem concentrations of CO2 in spring and summer were generally two times higher than those observed for trees without any decay in heartwood

Summary

Introduction

The global carbon cycle involves exchange of carbon between the atmosphere and marine and terrestrial biospheres, and sediments that include fossil fuels. For the past several decades, burning of fossil fuels and other human activities such as deforestation have produced a net CO2 increase in the atmosphere of 1–2 Pg (= 1015 g) each year [1]. Regarding the latter, forests play a major role in carbon cycling as they account for 80% of terrestrial carbon [3]. Maintenance of forest area, reforestation of former agricultural land, increased use of woody products and production of wood biomass for bio-energy are measures included in the climate change mitigation portfolio of the forest sector [2]

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