Mycorrhizal fungi and soil carbon storage

ectomycorrhizal fruting body- Amanita spp.

Soil carbon storage is an important function of terrestrial ecosystems. Soil contains more carbon than plants and the atmosphere combined.^[1] Understanding what maintains the soil carbon pool is important to understand the current distribution of carbon on Earth, and how it will respond to environmental change. While much research has been done on how plants, free-living microbial decomposers, and soil minerals affect this pool of carbon, it is recently coming to light that mycorrhizal fungi—symbiotic fungi that associate with roots of almost all living plants—may play an important role in maintaining this pool as well. Measurements of plant carbon allocation to mycorrhizal fungi have been estimated to be 5-20% of total plant carbon uptake,^[2][3] and in some ecosystems the biomass of mycorrhizal fungi can be comparable to the biomass of fine roots.^[4] Recent research has shown that mycorrhizal fungi hold 50 to 70 percent of the total carbon stored in leaf litter and soil on forested islands in Sweden.^[5] Turnover of mycorrhizal biomass into the soil carbon pool is thought to be rapid^[6] and has been shown in some ecosystems to be the dominant pathway by which living carbon enters the soil carbon pool.^[7]

Outlined below are the leading lines of evidence on how different aspects of mycorrhizal fungi may alter soil carbon decomposition and storage. Evidence is presented for arbuscular and ectomycorrhizal fungi separately as they are phylogenetically distinct and often function in very different ways.

Recalcitrance of mycorrhizal tissues

Based on the magnitude of mycorrhizal fungal inputs to the soil carbon pool, some have suggested that variation in the recalcitrance of mycorrhizal biomass may be important for predicting soil carbon storage, as it would affect the rate at which the contribution of mycorrhizal fungi to soil carbon is returned to the atmosphere.^[8] The compound glomalin, produced only by arbuscular mycorrhizal fungi, has been found to accumulate in some soils, and may be a substantial fraction of the soil carbon pool in these ecosystems.^[9] However, a recent set of experiments demonstrates the presence of arbuscular mycorrhizal fungi results in net losses of soil carbon,^[10] calling into question the role of glomalin produced by arbuscular mycorrhizal fungi leading to increased soil carbon storage.^[11] Proteomic work has revealed that most of the proteins isolated in the glomalin extraction are not of mycorrhizal origin, and therefore the contribution of this molecule to soil C storage has likely been overestimated.^[12]

Using a similar line of argument, Langley and Hungate (2003)^[13] argued that the abundance of chitin in ectomycorrhizal tissues may reduce decomposition rates of these fungi, under the assumption that chitin is recalcitrant. This possibility was tested and refuted recently. Fernandez and Koide (2012) show that chitin does not decompose more slowly than other chemical compounds in ectomycorrhizal tissues, and that chitin concentrations positively correlated with mycorrhizal biomass decomposition rates, rather than negatively.^[14]

Effects on fine root decomposition

Mycorrhizal fungi are nutrient rich structures compared to the roots they colonize, and it is possible that mycorrhizal colonization of roots leads to increased rates of root decomposition because decomposers would have greater access to nutrients. Evidence is equivocal on this point, as ectomycorrhizal colonization does increase fine root decomposition rates substantially compared to uncolonized roots in some ecosystems,^[15] while Pinus edulis roots colonized predominately by ectomycorrhizal fungi from the Ascomycota group have been found to decompose more slowly than uncolonized controls.^[16]

In an experiment where the effect of arbuscular mycorrhizal colonization on plant decomposition was tested,^[17] only aboveground plant material was found to have decomposed faster after 3 months while root decomposition remained unchanged, even though arbuscular mycorrhizal fungi are confined to roots.

Effects on soil aggregation

Soil aggregation can physically protect organic carbon from decay by soil microbes.^[18] More aggregate formation can result in more soil carbon storage. There is much evidence that arbuscular mycorrhizal fungi increase soil aggregate formation, and that aggregate formation may be mediated by the arbuscular mycorrhizal protein glomalin.^[19] Therefore, even if glomalin itself is not exceptionally recalcitrant and chemically resistant to decomposition (as described above) it may still contribute to soil carbon storage by physically protecting other organic matter from decomposition by promoting soil aggregation. There is little information regarding the role of ectomycorrhizal fungi in soil aggregate stability. There are anecdotal accounts of ectomycorrhizal fungi increasing aggregation in sand in-growth bags commonly used to trap these fungi,^[20] but no current evidence that they promote aggregate formation or stability in field soils.

Stimulation of decomposition (priming)

Arbuscular mycorrhizal fungi have been shown to increase soil carbon decomposition in nutrient rich patches.^[21] Since arbuscular mycorrhizal fungi are thought to lack the ability to produce the enzymes to catalyze this decomposition^[22] it is generally thought that they stimulate free-living decomposer communities to increase activity by exuding labile energy substrates, a process termed priming. Recent lab experiments have shown that the presence of arbuscular mycorrhizal fungi increases losses of soil carbon compared to soils where arbuscular mycorrhizal fungi are excluded, and that the difference is greater under elevated CO2 when the abundance of arbuscular mycorrhizal fungi is greater.^[23] The evidence for ectomycorrhizal priming is so far inconclusive. Field evidence suggests that ectomycorrhizal fungi may be increasing the rate of soil carbon degradation,^[24] however lab tests show that exudation from fine roots decreases with increasing ectomycorrhizal colonization,^[25] which suggests that abundance of ectomycorrhizal fungi should reduce priming effects. Brzostek et al. (2012) report variation in form of nitrogen produced in the rhizosphere of trees that vary in mycorrhizal type, however the effects of root and mycorrhizal priming could not be separated.^[26]

Inhibition of decomposition

The first report of mycorrhizal inhibition of decomposition was in 1971 and came from ectomycorrhizal Pinus radiatia plantations in New Zealand. Authors show that excluding roots and mycorrhizal fungi resulted in net carbon loss, and that the result could not be explained by soil disturbance effects.^[27] The mechanism presented is that ectomycorrhizal fungi can compete with free-living decomposers for nutrients, and thereby limit the rate of total decomposition. Since then there have been several other reports of ectomycorrhizal fungi reducing activity and decomposition rates of free-living decomposers and thereby increasing soil carbon storage.^[28][29][30] A theoretical ecosystem model recently demonstrated that greater access to organic nitrogen by mycorrhizal fungi should slow decomposition of soil carbon by free-living decomposers by inducing nutrient limitation.^[31] It should be noted however, that Koide and Wu (2003) made a strong case that the effect of ectomycorrhizal fungi on reducing decomposition may have more to do with competition for soil water than soil nutrients.^[32]

It is possible that arbuscular mycorrhizal fungi may be outcompeting free-living decomposers for either water or nutrients in some systems as well, however to date there is no demonstration of this, and it seems that arbuscular mycorrhizal fungi may more often increase, rather than decrease rates of decomposition by free-living microbial decomposers.^[33][34]

Further reading

Further reading on the role of arbuscular and ectomycorrhizal fungi in soil carbon storage and decomposition can be found in Zhu and Miller 2003 ^[35] and Ekblad et al. 2013,^[36] respectively.

• Mycorrhiza
• Arbuscular mycorrhiza
• Soil carbon
• Soil
• Decomposition
• Glomalin

References

1. ↑ Tarnocai et al. 2009. Soil organic carbon pools in the northern circumpolar permafrost region. Global Biogeochemical Cycles, 23(2) doi: 10.1029/2008GB003327
2. ↑ Pearson JN and Jakobsen I. 1993. The relative contribution of hyphae and roots to phosphorus uptake by arbuscular mycorrhizal plants, measured by dual labeling with 32P and 33P. New Phytologist, 124: 489-494.
3. ↑ Hobbie JE and Hobbie EA. 2006. 15N in symbiotic fungi and plants estimates nitrogen and carbon flux rates in arctic tundra. Ecology, 87: 816-822
4. ↑ Wallander H, Goransson H and Rosengren U. Production, standing biomass and natural abundance of 15N and 13C in ectomycorrhizal mycelia collected at different soil depths in two forest types. Oecologia, 139: 89-97.
5. ↑ K.E. Clemmensen et al. 2013. Roots and associated fungi drive long-term carbon sequestration in boreal forest. Science, 339: 1615-1618.
6. ↑ Staddon et al. 2003. Rapid turnover of hyphae of mycorrhizal fungi determined by AMS microanalysis of 14C. Science, 300: 1138-1140.
7. ↑ Godbold DL et al. 2006. Mycorrhizal hyphal turnover as a dominant process for carbon input into soil organic matter. Plant and Soil, 281: 15-24.
8. ↑ Langley JA and Hungate BA. 2003. Mycorrhizal controls on belowground litter quality. Ecology, 84: 2302-2312.
9. ↑ Rillig et al. 2001. Large contribution of arbuscular mycorrhizal fungi to soil carbon pools in tropical forest soils. Plant and Soil, 233: 167-177.
10. ↑ Cheng et al. 2012 Arbuscular mycorrhizal fungi increase organic carbon decomposition under elevated CO2. Science, 337: 1084-1087.
11. ↑ Verbruggen et al. 2013. Arbuscular mycorrhizal fungi – short-term liability but long-term benefits for soil carbon storage? New Phytologist, 197: 366-368.
12. ↑ Gillespie, Adam W., et al. "Glomalin-related soil protein contains non-mycorrhizal-related heat-stable proteins, lipids and humic materials." Soil Biology and Biochemistry 43.4 (2011): 766-777.
13. ↑ Langley JA and Hungate BA. 2003. Mycorrhizal controls on belowground litter quality. Ecology, 84: 2302-2312.
14. ↑ Fernandez CW and Koide RT. 2012. The role of chitin in the decomposition of ectomycorrhizal fungal litter. Ecology, 93: 24-28.
15. ↑ Koide RT, Fernandez CW and Peoples MS. 2011. Can ectomycorrhizal colonization of Pinus resinosa roots affect their decomposition? New Phytologist, 191: 508-514
16. ↑ Langley JA, Champman SK and Hungate BA. Ectomycorrhizal colonization slows root decomposition: the post-mortem fungal legacy. Ecology Letters, 9: 955-959
17. ↑ Urcelay C, Vaieretti MV, Pérez M, Díaz S. 2011. Effects of arbuscular mycorrhizal colonisation on shoot and root decomposition of different plant species and species mixtures. Soil Biology and Biochemistry 43: 466–468
18. ↑ Jastrow, J.D., and R.M. Miller. 1998. Soil aggregate stabilization and carbon sequestration: Feedbacks through organomineral associations, pp. 207-223. In R. Lal, J.M. Kimble, R.F. Follett, and B.A. Stewart (eds.) Soil Processes and the Carbon Cycle. CRC Press LLC, Boca Raton, FL.
19. ↑ Wilson, Gail WT, et al. Soil aggregation and carbon sequestration are tightly correlated with the abundance of arbuscular mycorrhizal fungi: results from long‐term field experiments. Ecology Letters 12.5 (2009): 452-461.
20. ↑ Wallander H, Nilsson LO, Hagerberg D and Baath E. 2001. Estimation of the biomass and seasonal growth of external mycelium of ectomycorrhizal fungi in the field. New Phytologist, 151: 753-760.
21. ↑ Hodge, Angela, Colin D. Campbell, and Alastair H. Fitter. 2001 An arbuscular mycorrhizal fungus accelerates decomposition and acquires nitrogen directly from organic material. Nature, 413: 297-299.
22. ↑ Read DJ and Perez-Moreno J. 2003. Mycorrhizas and nutrient cycling in ecosystems – a journey towards relevance? New Phytologist, 157: 475-492
23. ↑ Cheng et al. 2012 Arbuscular mycorrhizal fungi increase organic carbon decomposition under elevated CO2. Science, 337: 1084-1087.
24. ↑ Phillips RP et al. 2012. Roots and fungi accelerate carbon and nitrogen cycling in forests exposed to elevated CO2. Ecology Letters, 15: 1042-1049.
25. ↑ Meier, Ina C., Peter G. Avis, and Richard P. Phillips. Fungal communities influence root exudation rates in pine seedlings. FEMS microbiology ecology 83.3 (2013): 585-595.
26. ↑ Edward, R. Brzostek, Danilo Dragoni, and Richard P. Phillips. "Root carbon inputs to the rhizosphere stimulate extracellular enzyme activity and increase nitrogen availability in temperate forest soils." 97th ESA Annual Meeting. 2012.
27. ↑ Gadgil, Ruth L., and P. D. Gadgil. Mycorrhiza and litter decomposition. (1971): 133.
28. ↑ Berg B and Lindberg T. 1980. Is litter decomposition retarded in the presence of mycorrhizal roots in forest soil? Internal Report- Swedish Coniferous Forest Project, ISBN 91-7544-095-4
29. ↑ Lindahl BD, de Boer W and Finlay RD. 2010. Disruption of root carbon transport into forest humus stimulates fungal opportunists at the expense of mycorrhizal fungi. The ISME Journal, 4: 872-881.
30. ↑ McGuire KL et al. 2010. Slowed decomposition is biotically mediated in an ectomycorrhizal, tropical rain forest. Oecologia, 164: 785-795.
31. ↑ Orwin KH et al. Organic nutrient uptake by mycorrhizal fungi enhances ecosystem carbon storage: a model based assessment. Ecology Letters, 14: 493-502.
32. ↑ Koide RT and Wu T. 2003. Ectomycorrhizas and retarded decomposition in a Pinus resinosa plantation. New Phytologist, 158: 401-407.
33. ↑ Hodge, Angela, Colin D. Campbell, and Alastair H. Fitter. 2001 An arbuscular mycorrhizal fungus accelerates decomposition and acquires nitrogen directly from organic material. Nature, 413: 297-299.
34. ↑ Cheng et al. 2012 Arbuscular mycorrhizal fungi increase organic carbon decomposition under elevated CO2. Science, 337: 1084-1087.
35. ↑ Zhu YG and Miller RM. 2003. Carbon cycling by arbuscular mycorrhizal fungi in soil-plant systems. Trends in Plant Science, 8: 407-409.
36. ↑ Ekblad et al. 2013. The production and turnover of extrametrical mycelium of ectomycorrhizal fungi in forest soils: role in carbon cycling. Plant and Soil, 366: 1-27.