Methane Emission from Natural Wetlands: Interplay Between Emergent Macrophytes and Soil Microbial Processes. A Mini-review

Overview

Journal Ann Bot

Publisher Oxford University Press

Specialty Biology

Date 2009 Aug 20

PMID 19689973

Citations 40

Authors

Hendrikus J Laanbroek

Affiliations

Soon will be listed here.

Abstract

Background: According to the Intergovernmental Panel on Climate Change (IPCC) 2007, natural wetlands contribute 20-39 % to the global emission of methane. The range in the estimated percentage of the contribution of these systems to the total release of this greenhouse gas is large due to differences in the nature of the emitting vegetation including the soil microbiota that interfere with the production and consumption of methane.

Scope: Methane is a dominant end-product of anaerobic mineralization processes. When all electron acceptors except carbon dioxide are used by the microbial community, methanogenesis is the ultimate pathway to mineralize organic carbon compounds. Emergent wetland plants play an important role in the emission of methane to the atmosphere. They produce the carbon necessary for the production of methane, but also facilitate the release of methane by the possession of a system of interconnected internal gas lacunas. Aquatic macrophytes are commonly adapted to oxygen-limited conditions as they prevail in flooded or waterlogged soils. By this system, oxygen is transported to the underground parts of the plants. Part of the oxygen transported downwards is released in the root zone, where it sustains a number of beneficial oxidation processes. Through the pores from which oxygen escapes from the plant into the root zone, methane can enter the plant aerenchyma system and subsequently be emitted into the atmosphere. Part of the oxygen released into the root zone can be used to oxidize methane before it enters the atmosphere. However, the oxygen can also be used to regenerate alternative electron acceptors. The continuous supply of alternative electron acceptors will diminish the role of methanogenesis in the anaerobic mineralization processes in the root zone and therefore repress the production and emission of methane. The role of alternative element cycles in the inhibition of methanogenesis is discussed.

Conclusions: The role of the nitrogen cycle in repression of methane production is probably low. In contrast to wetlands particularly created for the purification of nitrogen-rich waste waters, concentrations of inorganic nitrogen compounds are low in the root zones in the growing season due to the nitrogen-consuming behaviour of the plant. Therefore, nitrate hardly competes with other electron acceptors for reduced organic compounds, and repression of methane oxidation by the presence of higher levels of ammonium will not be the case. The role of the iron cycle is likely to be important with respect to the repression of methane production and oxidation. Iron-reducing and iron-oxidizing bacteria are ubiquitous in the rhizosphere of wetland plants. The cycling of iron will be largely dependent on the size of the oxygen release in the root zone, which is likely to be different between different wetland plant species. The role of the sulfur cycle in repression of methane production is important in marine, sulfate-rich ecosystems, but might also play a role in freshwater systems where sufficient sulfate is available. Sulfate-reducing bacteria are omnipresent in freshwater ecosystems, but do not always react immediately to the supply of fresh sulfate. Hence, their role in the repression of methanogenesis is still to be proven in freshwater marshes.

Citing Articles

Metabolic interactions underpinning high methane fluxes across terrestrial freshwater wetlands.

Bechtold E, Ellenbogen J, Villa J, de Melo Ferreira D, Oliverio A, Kostka J Nat Commun. 2025; 16(1):944.

PMID: 39843444 PMC: 11754854. DOI: 10.1038/s41467-025-56133-0.

Microbial Community Changes across Time and Space in a Constructed Wetland.

Elhaj Baddar Z, Bier R, Spencer B, Xu X ACS Environ Au. 2024; 4(6):307-316.

PMID: 39582758 PMC: 11583098. DOI: 10.1021/acsenvironau.4c00021.

Unraveling Spatially Diverse and Interactive Regulatory Mechanisms of Wetland Methane Fluxes to Improve Emission Estimation.

Guo H, Cui S, Nielsen C, Pullens J, Qiu C, Wu S Environ Sci Technol. 2024; .

PMID: 39134052 PMC: 11360361. DOI: 10.1021/acs.est.4c06057.

Comparative flooding tolerance of Typha latifolia and Phalaris arundinacea in wetland restoration: Insights from photosynthetic CO response curves, photobiology and biomass allocation.

Jensen A, Eller F, Sorrell B Heliyon. 2024; 10(1):e23657.

PMID: 38187246 PMC: 10767378. DOI: 10.1016/j.heliyon.2023.e23657.

Multiple microbial guilds mediate soil methane cycling along a wetland salinity gradient.

Hartman W, de Mesquita C, Theroux S, Morgan-Lang C, Baldocchi D, Tringe S mSystems. 2024; 9(1):e0093623.

PMID: 38170982 PMC: 10804969. DOI: 10.1128/msystems.00936-23.

References

Nijburg J, Coolen M, Gerards S, Gunnewiek P, Laanbroek H . Effects of Nitrate Availability and the Presence of Glyceria maxima on the Composition and Activity of the Dissimilatory Nitrate-Reducing Bacterial Community. Appl Environ Microbiol. 1997; 63(3):931-7. PMC: 1389122. DOI: 10.1128/aem.63.3.931-937.1997. View

Ding W, Cai Z, Tsuruta H, Li X . Key factors affecting spatial variation of methane emissions from freshwater marshes. Chemosphere. 2003; 51(3):167-73. DOI: 10.1016/s0045-6535(02)00804-4. View

Cheng X, Peng R, Chen J, Luo Y, Zhang Q, An S . CH4 and N2O emissions from Spartina alterniflora and Phragmites australis in experimental mesocosms. Chemosphere. 2007; 68(3):420-7. DOI: 10.1016/j.chemosphere.2007.01.004. View

Sand-Jensen K, Pedersen O, Binzer T, Borum J . Contrasting oxygen dynamics in the freshwater isoetid Lobelia dortmanna and the marine seagrass Zostera marina. Ann Bot. 2005; 96(4):613-23. PMC: 4247029. DOI: 10.1093/aob/mci214. View

Miletto M, Loy A, Antheunisse A, Loeb R, Bodelier P, Laanbroek H . Biogeography of sulfate-reducing prokaryotes in river floodplains. FEMS Microbiol Ecol. 2008; 64(3):395-406. DOI: 10.1111/j.1574-6941.2008.00490.x. View

Emerson , Weiss , Megonigal . Iron-oxidizing bacteria are associated with ferric hydroxide precipitates (Fe-plaque) on the roots of wetland plants . Appl Environ Microbiol. 1999; 65(6):2758-61. PMC: 91409. DOI: 10.1128/AEM.65.6.2758-2761.1999. View

Roden E, Wetzel R . Competition between Fe(III)-reducing and methanogenic bacteria for acetate in iron-rich freshwater sediments. Microb Ecol. 2003; 45(3):252-8. DOI: 10.1007/s00248-002-1037-9. View

Klepac-Ceraj V, Bahr M, Crump B, Teske A, Hobbie J, Polz M . High overall diversity and dominance of microdiverse relationships in salt marsh sulphate-reducing bacteria. Environ Microbiol. 2004; 6(7):686-98. DOI: 10.1111/j.1462-2920.2004.00600.x. View

Purvaja R, Ramesh R . Natural and anthropogenic methane emission from coastal wetlands of South India. Environ Manage. 2001; 27(4):547-57. DOI: 10.1007/s002670010169. View

10.

Wang J, Muyzer G, Bodelier P, Laanbroek H . Diversity of iron oxidizers in wetland soils revealed by novel 16S rRNA primers targeting Gallionella-related bacteria. ISME J. 2009; 3(6):715-25. DOI: 10.1038/ismej.2009.7. View

11.

Brunel B, Janse J, Laanbroek H, Woldendorp J . Effect of transient oxic conditions on the composition of the nitrate-reducing community from the rhizosphere of Typha angustifolia. Microb Ecol. 2013; 24(1):51-61. DOI: 10.1007/BF00171970. View

12.

Van Der Nat F, De Brouwer J, Middelburg J, Laanbroek H . Spatial distribution and inhibition by ammonium of methane oxidation in intertidal freshwater marshes. Appl Environ Microbiol. 2006; 63(12):4734-40. PMC: 1389306. DOI: 10.1128/aem.63.12.4734-4740.1997. View

13.

Bodelier P, Laanbroek H . Nitrogen as a regulatory factor of methane oxidation in soils and sediments. FEMS Microbiol Ecol. 2009; 47(3):265-77. DOI: 10.1016/S0168-6496(03)00304-0. View

14.

King G, Garey M . Ferric iron reduction by bacteria associated with the roots of freshwater and marine macrophytes. Appl Environ Microbiol. 1999; 65(10):4393-8. PMC: 91583. DOI: 10.1128/AEM.65.10.4393-4398.1999. View

15.

Pedersen O, Vos H, Colmer T . Oxygen dynamics during submergence in the halophytic stem succulent Halosarcia pergranulata. Plant Cell Environ. 2006; 29(7):1388-99. DOI: 10.1111/j.1365-3040.2006.01522.x. View

16.

Choi J, Park S, Jaffe P . The effect of emergent macrophytes on the dynamics of sulfur species and trace metals in wetland sediments. Environ Pollut. 2005; 140(2):286-93. DOI: 10.1016/j.envpol.2005.07.009. View

17.

Vretare Strand V, Weisner S . Interactive effects of pressurized ventilation, water depth and substrate conditions on Phragmites australis. Oecologia. 2017; 131(4):490-497. DOI: 10.1007/s00442-002-0915-7. View

18.

Johansson A, Gustavsson A, Oquist M, Svensson B . Methane emissions from a constructed wetland treating wastewater--seasonal and spatial distribution and dependence on edaphic factors. Water Res. 2004; 38(18):3960-70. DOI: 10.1016/j.watres.2004.07.008. View

19.

Calhoun A, King G . Regulation of root-associated methanotrophy by oxygen availability in the rhizosphere of two aquatic macrophytes. Appl Environ Microbiol. 1997; 63(8):3051-8. PMC: 1389221. DOI: 10.1128/aem.63.8.3051-3058.1997. View

20.

Dacey J . Internal winds in water lilies: an adaptation for life in anaerobic sediments. Science. 1980; 210(4473):1017-9. DOI: 10.1126/science.210.4473.1017. View