The role of filamentous algae Spirogyra spp. in methane production and emissions in streams

详细信息    查看全文

• 作者：Xia Liang ; Xiuyun Zhang ; Qiao Sun ; Chiquan He ; Xueping Chen…
• 关键词：Methane emission ; Methane production ; Stream ; Filamentous algae ; Dissolved organic carbon
• 刊名：Aquatic Sciences - Research Across Boundaries
• 出版年：2016
• 出版时间：April 2016
• 年：2016
• 卷：78
• 期：2
• 页码：227-239
• 全文大小：973 KB
• 参考文献：Albay M, Akçaalan R (2008) Effects of water quality and hydrologic drivers on periphyton colonization on Sparganium erectum in two Turkish lakes with different mixing regimes. Environ Monit Assess 146(1–3):171–181CrossRef PubMed
  Andrew SE, Schultz R, Frey SD, Bouchard V, Varner R, Ducey M (2013) Plant community structure mediates potential methane production and potential iron reduction in wetland mesocosms. Ecosphere 4:art44
  Atkinson CL, Golladay SW, Opsahl SP, Covich AP (2009) Stream discharge and floodplain connections affect seston quality and stable isotopic signatures in a coastal plain stream. J N Am Benthol Soc 28:360–370CrossRef
  Augspurger C, Küsel K (2010) Flow velocity and primary production influences carbon utilization in nascent epilithic stream biofilms. Aquat Sci 72:237–243CrossRef
  Bastviken D, Cole J, Pace M, Tranvik L (2004) Methane emissions from lakes: dependence of lake characteristics, two regional assessments, and a global estimate. Global Biogeochem Cycles 18:GB4009CrossRef
  Battin TJ, Luyssaert S, Kaplan LA, Aufdenkampe AK, Richter A, Tranvik LJ (2009) The boundless carbon cycle. Nat Geosci 2:598–600CrossRef
  Baulch HM, Dillon PJ, Maranger R, Schiff SL (2011) Diffusive and ebullitive transport of methane and nitrous oxide from streams: are bubble–mediated fluxes important? J Geophys Res 116:G04028CrossRef
  Bischoff HW, Bold HC (1963) Phycological studies. IV. Some soil algae from enchanted rock and related algal species. University of Texas Publication, Texas, pp 1–95
  Blodau C, Siems M (2012) Drainage–induced forest growth alters belowground carbon biogeochemistry in the Mer Bleue bog, Canada. Biogeochemistry 107:107–123CrossRef
  Bloom AA, Palmer PI, Fraser A, Reay DS (2012) Seasonal variability of tropical wetland CH4 emissions: the role of the methanogen-available carbon pool. Biogeosciences 9:2821–2830CrossRef
  Bogard MJ, del Giorgio PA, Boutet L, Chaves MC, Prairie YT, Merante A, Derry AM (2014) Oxic water column methanogenesis as a major component of aquatic CH4 fluxes. Nat Commun 5:5350CrossRef PubMed
  Boisson JC, Perrodin Y (2006) Effects of road runoff on biomass and metabolic activity of periphyton in experimental streams. J Hazard Mater A 132:148–154CrossRef
  Boston HL, Hill WR, Stewart AJ (1991) Evaluating direct toxicity and food-chain effects in aquatic systems using natural periphyton communities. In: Gorsuch JW, William RL, Lewis AL, Wang W (eds) Plants for toxicity assessment. American Society for Testing and Materials, Philadelphia, pp 126–145CrossRef
  Bridgham SD, Cadillo-Quiroz H, Keller JK, Zhuang Q (2013) Methane emissions from wetlands: biogeochemical, microbial, and modeling perspectives from local to global scales. Glob Chang Bio 19:1325–1346CrossRef
  Browder JA, Gleason PJ, Swift DR (1994) Periphyton in the Everglades: spatial variation, environmental correlates, and ecological implications. In: Davis SM, Ogden JC (eds) Everglades: the ecosystem and its restoration. St. Lucie Press, Florida, pp 379–419
  Campeau A, Lapierre JF, Vachon D, del Giorgio PA (2014) Regional contribution of CO2 and CH4 fluxes from the fluvial network in a lowland boreal landscape of Québec. Global Biogeochem Cycles 28:57–69CrossRef
  Chin KJ, Lueders T, Friedrich MW, Klose M, Conrad R (2004) Archaeal community structure and pathway of methane formation on rice roots. Microb Ecol 47:59–67CrossRef PubMed
  Cogan NG, Keener JP (2004) The role of the biofilm matrix in structural development. Math Med Biol 21:147–166CrossRef PubMed
  Cole JJ, Bade DL, Bastviken D, Pace ML, Van de Bogert M (2010) Multiple approaches to estimating air–water gas exchange in small lakes. Limnol Oceanogr Methods 8:285–293CrossRef
  Crawford JT, Striegl RG, Wickland KP, Dornblaser MM, Stanley EH (2013) Emissions of carbon dioxide and methane from a headwater stream network of interior Alaska. J Geophys Res Biogeosci 118:482–494CrossRef
  Crawford JT, Stanley EH, Spawn SA, Finlay JC, Loken LC, Striegl RG (2014) Ebullitive methane emissions from oxygenated wetland streams. Glob Chang Biol 20:3408–3422CrossRef PubMed
  Dean WE (1974) Determination of carbonate and organic matter in calcareous sediments and sedimentary rocks by loss on ignition: comparison with other methods. J Sed Pet 44:242–248
  Dorodnikov M, Knorr KH, Kuzyakov Y, Wilmking M (2011) Plant-mediated CH4 transport and contribution of photosynthates to methanogenesis at a boreal mire: a C-14 pulse-labeling study. Biogeosciences 8:2365–2375CrossRef
  Dunfield P, Knowles R, Dumont R (1993) Methane production and consumption in temperate and subarctic peat soils: response to temperature and pH. Soil Biol Biochem 25:321–326CrossRef
  Fritz C, Pancotto VA, Elzenga JTM, Visser EJW, Grootjans AP, Pol A, Iturraspe R, Roelofs JGM, Smolders AJP (2011) Zero methane emission bogs: extreme rhizosphere oxygenation by cushion plants in Patagonia. New Phytol 190:398–408CrossRef PubMed
  Hainz R, Wöber C, Schagerl M (2009) The relationship between Spirogyra (Zygnematophyceae, Streptophyta) filament type groups and environmental conditions in Central Europe. Aquat Bot 91(3):173–180CrossRef
  Han M, Shu Y (1995) Atlas of freshwater biota in China. China Ocean Press, Beijing
  Han H, Chen Y, Jørgensen SE, Nielsen SN, Hu W (2009) A system-dynamic model on the competitive growth between Potamogeton malaianus Miq. and Spirogyra sp. Ecol Model 220:2206–2217CrossRef
  Hill KE, Marchesi JR, Fry JC (1996) Conjugation and mobilization in the epilithon. In: Akkermans ADL, Van Elsas JD, De Bruijn FJ (eds) Molecular microbial ecology manual. Kluwer Academic Publishers, Dordrecht, pp 125–152CrossRef
  Hope D, Palmer SM, Billett MF, Dawson JJC (2001) Carbon dioxide and methane evasion from a temperate peatland stream. Limnol Oceanogr 46:847–857CrossRef
  Irfanullah HM, Moss B (2005) Allelopathy of filamentous green algae. Hydrobiologia 543:169–179CrossRef
  Juottonen H, Tuittila ES, Juutinen S, Fritze H, Yrjälä K (2008) Seasonality of rDNA– and rRNA–derived archaeal communities and methanogenic potential in a boreal mire. ISME J 2:1157–1168CrossRef PubMed
  Kalscheur KN, Rojas M, Peterson CG, Kelly JJ, Gray KA (2012) Algal exudates and stream organic matter influence the structure and function of denitrifying bacterial communities. Microbial Ecol 64:881–892CrossRef
  Kankaala P, Käki T, Ojala A (2003) Quality of detritus impacts on spatial variation of methane emissions from littoral sediment of a boreal lake. Arch Hydrobiol 157:47–66CrossRef
  Kankaala P, Käki T, Mäkelä S, Ojala A, Pajunen H, Arvola L (2005) Methane efflux in relation to plant biomass and sediment characteristics in stands of three common emergent macrophytes in boreal mesoeutrophic lakes. Glob Chang Biol 11:145–153CrossRef
  Kearns KD, Hunter MD (2000) Green algal extracellular products regulate antialgal toxin production in a cyanobacterium. Environ Microbiol 2:291–297CrossRef PubMed
  King JY, Reeburgh WS, Thieler KK, Kling GW, Loya WM, Johnson LC, Nadelhoffer KJ (2002) Pulse-labeling studies of carbon cycling in Arctic tundra ecosystems: the contribution of photosynthates to methane emission. Global Biogeochem Cy 16:1062CrossRef
  Kleeberg A, Schubert H, Koschorreck M, Nixdorf B (2006) Abundance and primary production of filamentous green algae Zygogonium ericetorum in an extremely acid (pH 2.9) mining lake and its impact on alkalinity generation. Freshw Biol 51:925–937CrossRef
  Koelbener A, Ström L, Edwards P, Venterink H (2010) Plant species from mesotrophic wetlands cause relatively high methane emissions from peat soil. Plant Soil 326:147–158CrossRef
  Kritzberg ES, Cole JJ, Pace ML, Granéli W, Blade DL (2004) Autochthonous versus allochthonous carbon sources of bacteria: results from whole-lake 13C addition experiments. Limnol Oceanogr 49:588–596CrossRef
  Kritzberg ES, Cole JJ, Pace MM, Granéli W (2005) Does autochthonous primary production drive variability in bacterial metabolism and growth efficiency in lakes dominated by terrestrial C inputs? Aquat Microb Ecol 38:103–111CrossRef
  Leigh C, Burford MA, Sheldon F, Bunn SE (2010) Dynamic stability in dry season food webs within tropical floodplain rivers. Mar Freshw Res 61:357–368CrossRef
  Leonard L, Croft A, Childers D, Mitchell-Bruker S, Solo-Gabriele H, Ross M (2006) Characteristics of surface-water flows in the ridge and slough landscape of Everglades National Park: implications for particulate transport. Hydrobiologia 569:5–22CrossRef
  Liang X (2007) Effect of periphyton on water environment and its application in water quality treatment. Ph.D. thesis, East China Normal University, Shanghai, p 71
  Liang X, Li X (2008) Treatment of polluted urban river water using filamentous green algae. Environ Sci 29(1):52–57 (in Chinese)
  Megonigal JP, Whalen SC, Tissue DT, Bovard BD, Albert DB, Allen AS (1999) A plant-soil-atmosphere microcosm for tracing radiocarbon from photosynthesis through methanogenesis. Soil Sci Soc Am J 63:665–671CrossRef
  Mer JL, Roger P (2001) Production, oxidation, emission and consumption of methane by soils: a review. Eur J Soil Biol 37:25–50CrossRef
  Mohan SV, Rao CN, Prasad KK, Karthikeyan J (2002) Treatment of simulated reactive yellow 22 (Azo) dye effluents using Spirogyra species. Waste Manag 22:575–582CrossRef PubMed
  Münster U, Einiö P, Nurminen J, Overbeck J (1992) Extracellular enzymes in a polyhumic lake: important regulators in detritus processing. In: Salonen K, Kairesalo T, Jones RI (eds) Dissolved Organic Matter in Lacustrine Ecosystems: energy source and system regulator. Developments in Hydrobiology 73. Kluwer Academic Publishers, Dordrecht, pp 225–238 Reprinted from Hydrobiologia, 229 CrossRef
  Nahlik AM, Mitsch WJ (2010) Methane emissions from created riverine wetlands. Wetlands 30:783–793CrossRef
  Nahlik AM, Mitsch WJ (2011) Methane emissions from tropical freshwater wetlands located in different climatic zones of Costa Rica. Glob Chang Biol 17:1321–1334CrossRef
  Neu T, Lawrence J (2009) Extracellular polymeric substances in microbial biofilms. In: Moran A, Holst O, Brenan P, von Itzstein M (eds) Microbial glycobiology: structures, relevance and applications. Elsevier, London, pp 735–758
  Opsahl RW, Welnitz T, Poff NL (2003) Current velocity and invertebrate grazing regulate stream algae: results of an in situ electrical exclusion. Hydrobiologia 499:135–145CrossRef
  Paver SF, Kent AD (2010) Temporal patterns in glycolate-utilizing bacterial community composition correlate with phytoplankton population dynamics in humic lakes. Microbial Ecol 60:406–418CrossRef
  Philippot L, Hallin S, Börjesson G, Baggs EM (2009) Biochemical cycling in the rhizosphere having an impact on global change. Plant Soil 321(1–2):61–81CrossRef
  Power ME, Stewart AJ (1987) Disturbance and recovery of an algal assemblage following flooding in an Oklahoma stream. Am Midl Nat 117:333–345CrossRef
  Power ME, Parker MS, Dietrich WE (2008) Seasonal reassembly of a river food web: floods, droughts, and impacts of fish. Ecol Monogr 78:263–282CrossRef
  Power ME, Lowe R, Furey PC, Welter J, Limm M, Finlay J, Bode C, Chang S, Goodrich M, Sculley J (2009) Algal mats and insect emergence in rivers under Mediterranean climates: towards photogrammetric surveillance. Freshw Biol 54(10):2101–2115CrossRef
  Roach KA, Winemiller KO, Layman CA, Zeug SC (2009) Consistent trophic patterns among fishes in lagoon and channel habitats of a tropical floodplain river: evidence from stable isotopes. Acta Oecol 35:513–522CrossRef
  Romaní AM, Sabater S (1999) Epilithic ectoenzyme activity in a nutrient-rich Mediterranean river. Aquat Sci 61:122–132CrossRef
  Sander R (1999) Compilation of Henry’s law constants for inorganic and organic species of potential importance in environmental chemistry. max-planck institute of chemistry, Mainz, Germany. Available on-line at http://​www.​mpch-mainz.​mpg.​de/​~sander/​res/​henry.​html
  Schultz R, Andrews S, O’Reilly L, Bouchard V, Frey S (2011) Plant community composition more predictive than diversity of carbon cycling in freshwater wetlands. Wetlands 31:965–977CrossRef
  Schulz S, Conrad R (1995) Effect of algal deposition on acetate and methane concentrations in the profundal sediment of a deep lake (Lake Constance). FEMS Microbiol Ecol 16:251–260CrossRef
  Schwarz JIK, Eckert W, Conrad R (2008) Response of the methanogenic microbial community of a profundal lake sediment (Lake Kinneret, Israel) to algal deposition. Limnol Oceanogr 53:113–121CrossRef
  Serrano-Silva N, Sarria-Guzmán Y, Dendooven L, Luna-Guido M (2014) Methanogenesis and methanotrophy in soil: a review. Pedosphere 24(3):291–307CrossRef
  Shakun JD, Clark PU, He F, Marcott SA, Mix AC, Liu Z, Otto-Bliesner B, Schmittner A, Bard E (2012) Global warming preceded by increasing carbon dioxide concentrations during the last deglaciation. Nature 484:49–54CrossRef PubMed
  Singh A, Dubey SK (2012) Temporal variation in methanogenic community structure and methane production potential of tropical rice ecosystem. Soil Biol Biochem 48:162–166CrossRef
  Smith KA, Ball T, Conen F, Dobbie KE, Massheder J, Rey A (2003) Exchange of greenhouse gases between soil and atmosphere: interactions of soil physical factors and biological processes. Eur J Soil Sci 54:779–791CrossRef
  Stamp I, Baird AJ, Heppell CM (2013) The importance of ebullition as a mechanism of methane (CH4) loss to the atmosphere in a northern peatland. Geophys Res Lett 40:2087–2090CrossRef
  Stewart PS (2003) Diffusion in biofilms. J Bacteriol 185:1485–1491CrossRef PubMed PubMedCentral
  Stocker BD, Roth R, Joos F, Spahni R, Steinacher M, Zaehle S, Bouwman L, Xu-Ri Prentice IC (2013) Multiple greenhouse–gas feedbacks from the land biosphere under future climate change scenarios. Nat Clim Change 3:666–672CrossRef
  Striegl RG, Dornblaser MM, McDonald CP, Rover JR, Stets EG (2012) Carbon dioxide and methane emissions from the Yukon River system. Global Biogeochem Cycles 26(4):GB0E05CrossRef
  Sun X, Song C, Guo Y, Wang X, Yang G, Li Y, Mao R, Lu Y (2012) Effect of plants on methane emissions from a temperate marsh in different seasons. Atmos Environ 60:277–282CrossRef
  Sundh I, Bell RT (1992) Extracellular dissolved organic carbon released from phytoplankton as a source of carbon for heterotrophic bacteria in lakes of different humic content. Hydrobiologia 229:93–106CrossRef
  Sutton-Grier AE, Megonigal JP (2011) Plant species traits regulate methane production in freshwater wetland soils. Soil Biol Biochem 43:413–420CrossRef
  Szabo S, Scheffer M, Roijackers R, Waluto B, Braun M, Nagy PT, Borics G, Zambrano L (2010) Strong growth limitation of a floating plant (Lemna gibba) by the submerged macrophyte (Elodea nuttallii) under laboratory conditions. Freshw Biol 55:681–690CrossRef
  Tonkin JD, Death RG (2014) The combined effects of flow regulation and an artificial flow release on a regulated river. River Res Appl 30:329–337CrossRef
  Townsend SA, Padovan AV (2005) The seasonal accrual and loss of benthic algae (Spirogira) in the Daily River, an oligotrophic river in tropical Australia, Mar. Freshw Res 56:317–327CrossRef
  Uz I, Chauhan A, Ogram AV (2007) Cellulolytic, fermentative, and methanogenic guilds in benthic periphyton mats from the Florida Everglades. FEMS Microbiol Ecol 61:337–347CrossRef PubMed
  Vilches C, Giorgi A, Casco MA (2013) Periphyton responses to non-point pollution in naturally eutrophic conditions in Pampean streams. Fund Appl Limnol 183:63–74CrossRef
  West WE, Coloso JJ, Jones SE (2012) Effects of algal and terrestrial carbon on methane production rates and methanogen community structure in a temperate lake sediment. Freshw Biol 57:949–955CrossRef
  Wetzel RG (1983) Periphyton of freshwater ecosystems. Dr. W Junk Publishers, Dordrecht, p 346CrossRef
  Wright AL, Reddy KR (2008) Catabolic diversity of periphyton and detritus microbial communities in a subtropical wetland. Biogeochemistry 89:199–207CrossRef
  Yamada Y, Mito Y, Igeta A, Wada E (2012) Dissolved oxygen concentration in river sediment of the Lake Biwa tributaries, Japan. Limnology 13:149–154CrossRef
  Ye R, Jin Q, Bohannan B, Keller JK, McAllister SA, Bridgham SD (2012) pH controls over anaerobic carbon mineralization, the efficiency of methane production, and methanogenic pathways in peatlands across an ombrotrophic–minerotrophic gradient. Soil Biol Biochem 54:36–47CrossRef
  Yu Z, Deng H, Wang D, Ye M, Tan Y, Li Y, Chen Z, Xu S (2013) Nitrous oxide emissions in the Shanghai river network: implications for the effects of urban sewage and IPCC methodology. Global Change Biol 19:2999–3010CrossRef
  Zar JH (1984) Biostatistical analysis, 2nd edn. Prentice-Hall, Englewood Cliffs, p 718
  Zeug SC, Winemiller KO (2008) Evidence supporting the importance of terrestrial carbon in a large-river food web. Ecology 89:1733–1743CrossRef PubMed
  Ziegler SE, Lyon DR, Townsend SL (2009) Carbon release and cycling within epilithic biofilms in two contrasting headwater streams. Aquat Microb Ecol 55(3):285–300CrossRef
  Zulkifly S, Hanshew A, Young EB, Lee P, Graham ME, Graham ME, Piotrowski M, Graham LE (2012) The epiphytic microbiota of the globally widespread macroalga Cladophora glomerata (Chlorophyta, Cladophorales). Am J Bot 99:1541–1552CrossRef PubMed
  
• 作者单位：Xia Liang (1)
  Xiuyun Zhang (1)
  Qiao Sun (1)
  Chiquan He (1)
  Xueping Chen (1)
  Xiaoyan Liu (1)
  Zhenlou Chen (2)
  
  1. School of Environmental and Chemical Engineering, Shanghai University, 99 Shangda Road, 200444, Shanghai, China
  2. School of Resources and Environment Science, East China Normal University, 500 Dongchuan Road, 200241, Shanghai, China
  
• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Life Sciences
  Ecology
  Oceanography
  Life Sciences
  
• 出版者：Birkh盲user Basel
• ISSN：1420-9055

文摘

Periphyton is an important primary producer in freshwater ecosystems. However, their effects on methane (CH₄) production and emissions in streams and rivers are not fully understood. The purpose of this study was to investigate the effects of filamentous algae Spirogyra spp. on CH₄ flux and to characterize the factors responsible for these effects. Sediments cores were collected from a stream in the suburbs of Shanghai and either inoculated with Spirogyra spp. in the laboratory or left uninoculated. CH₄ flux, dissolved CH₄ concentration, potential CH₄ production rate and organic carbon in sediments and overlying water were measured for 2 months. Study results indicated that CH₄ fluxes in algal treatment columns were significantly higher than in unvegetated sediments during initial algal decomposition, while potential CH₄ production rates in algal treatment columns were significantly higher than in controls during both algal bloom and initial decomposition. The relationship between CH₄ flux and environmental parameters was assessed and CH₄ flux was found to exhibit a strongly positive relationship with dissolved organic carbon (DOC) concentration and potential CH₄ production rate during experimental periods. It was concluded that Spirogyra spp. increased CH₄ emissions in streams by providing algal carbon sources for methanogenesis and stimulating the CH₄ production in sediments. These findings may facilitate understanding the roles of periphyton in aquatic methane dynamics and global greenhouse gas emissions.