Salt Marshes as Potential Indicators of Global Climate Change

Kim, Dae Hyun; Bartholdy, Jesper; Jung, Soohyun; Cairns, David M.

doi:10.1111/j.1749-8198.2011.00421.x

Cited by 12 publications

(4 citation statements)

References 94 publications

(198 reference statements)

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“…Significant deterioration of salt marshes along the Louisiana coastline has been linked to natural stressors (in many cases exacerbated by anthropogenic activities), such as hurricanes, sea-level rise, subsidence, and diminishing sediment supply (4)(5)(6)(7)(8) and to direct anthropogenic stressors from canal development, introduction of invasive species, pervasive nutrient pulses, pollutant accumulation, and freshwater flooding due to river diversions (9)(10)(11), as well as from accidents such as chemical and oil spills (12 and 13-16). The Deepwater Horizon (DWH) explosion and Macondo Prospect well blowout in the Mississippi Canyon Block 252 (MC252) on 20 April 2010 released an estimated 4.9 million barrels of Louisiana sweet crude oil into the Gulf of Mexico (17).…”

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confidence: 99%

“…However, although microorganisms are known to regulate marsh biogeochemical reactions (6,23,24), predicting whether and how marsh microbial communities would respond to the DWH oil spill was a challenge because diversity had been understudied (8,16,25,26), and almost nothing was known about community functional redundancy that could enhance response and resistance (20,21,(27)(28)(29)(30). Initially, some DWH spill researchers proposed a swift microbial response (16,17) because microbes have the capacity to degrade constituent carbon compounds in oil (31)(32)(33)(34)(35) and earlier nutrient enrichment, metal exposure, and oiling experiments provided evidence that marsh communities could withstand low levels of disturbance from an oil spill (25,36).…”

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Salt Marsh Bacterial Communities before and after the Deepwater Horizon Oil Spill

Engel

Liu

Paterson

et al. 2017

Appl Environ Microbiol

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Coastal salt marshes along the northern Gulf of Mexico shoreline received varied types and amounts of weathered oil residues after the 2010 Deepwater Horizon oil spill. At the time, predicting how marsh bacterial communities would respond and/or recover to oiling and other environmental stressors was difficult because baseline information on community composition and dynamics was generally unavailable. Here, we evaluated marsh vegetation, physicochemistry, flooding frequency, hydrocarbon chemistry, and subtidal sediment bacterial communities from 16S rRNA gene surveys at 11 sites in southern Louisiana before the oil spill and resampled the same marshes three to four times over 38 months after the spill. Calculated hydrocarbon biomarker indices indicated that oil replaced native natural organic matter (NOM) originating from Spartina alterniflora and marine phytoplankton in the marshes between May 2010 and September 2010. At all the studied marshes, the major class-and order-level shifts among the phyla Proteobacteria, Firmicutes, Bacteroidetes, and Actinobacteria occurred within these first 4 months, but another community shift occurred at the time of peak oiling in 2011. Two years later, hydrocarbon levels decreased and bacterial communities became more diverse, being dominated by Alphaproteobacteria (Rhizobiales), Chloroflexi (Dehalococcoidia), and Planctomycetes. Compositional changes through time could be explained by NOM source differences, perhaps due to vegetation changes, as well as marsh flooding and salinity excursions linked to freshwater diversions. These findings indicate that persistent hydrocarbon exposure alone did not explain long-term community shifts. IMPORTANCE Significant deterioration of coastal salt marshes in Louisiana has been linked to natural and anthropogenic stressors that can adversely affect how ecosystems function. Although microorganisms carry out and regulate most biogeochemical reactions, the diversity of bacterial communities in coastal marshes is poorly known, with limited investigation of potential changes in bacterial communities in response to various environmental stressors. The Deepwater Horizon oil spill provided an unprecedented opportunity to study the long-term effects of an oil spill on microbial systems in marshes. Compared to previous studies, the significance of our research stems from (i) a broader geographic range of studied marshes, (ii) an extended time frame of data collection that includes prespill conditions, (iii) a more accurate procedure using biomarker indices to understand oiling, and (iv) an examination of other potential stressors linked to in situ environmental changes, aside from oil exposure.

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confidence: 99%

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Salt Marsh Bacterial Communities before and after the Deepwater Horizon Oil Spill

Engel

Liu

Paterson

et al. 2017

Appl Environ Microbiol

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“…Many studies have assessed the causes and consequences of saltmarsh loss (Eliot et al, 1999, Miller et al, 2001, Wu et al, 2002, Cahoon et al, 2006, Marfai and King, 2008, including in Portugal (Moreira, 1986;Ferreira et al, 2008). Degradation and loss of saltmarshes have major implications to their capacity of delivering ecosystem services, including: sediment accumulation; nutrients cycling; filtering of contaminants; wildlife habitat; flood regulation and storm protection (Simas et al, 2001;Currin et al, 2008;Feagin et al, 2008;Gedan and Bertness, 2010;Kim et al, 2011). The extension, exposure and orientation of the saltmarsh in relation to the coast, and the vegetation cover and maturity level of the plant communities influence the capacity to provide ecosystem services.…”

Section: Introductionmentioning

confidence: 99%

The impacts of land-use changes on the recovery of saltmarshes in Portugal

Almeida

Neto

Esteves

et al. 2014

Ocean & Coastal Management

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Human-induced land-use changes have resulted in loss and degradation of intertidal environments worldwide. Saltmarsh ecosystem dynamics in Portugal are greatly influenced by historic uses and consequent habitat degradation. This study uses an original approach combining vegetation surveys and spatial analysis of historic maps and aerial photographs to assess the effects of land use changes on saltmarshes in two areas in the Algarve, southern Portugal. Historical maps from c. 1800 and aerial photographs from 1958 to 2010 were analysed to map saltmarsh ecosystems and quantify land-use changes in the Alvor estuary and Arade River. Between c. 1800 and 2010 more than half of saltmarshes were lost due to dyke building and saltmarsh reclamation for agriculture. In mid-1960s, the abandonment of reclaimed agricultural areas resulted in the recolonization of saltmarsh vegetation, which developed physically separated from natural marshes. In the study area, these saltmarshes naturally evolved into two distinct typologies: (1) enclosed mixed marshes, formed by patches of brackish, freshwater and some invasive species developing due to saline intrusion in areas where dykes have not been breached; and (2) tidally-restored saltmarshes, formed in areas where dyke breaching allows incursion of tides and development of a vegetation structure similar to natural saltmarshes. In Europe, passive (without human intervention) and active (artificially planned) saltmarsh restoration are important mechanisms for voluntary or statutory re-creation of intertidal habitats. Improved understanding of the factors influencing the development of distinct saltmarsh typologies through passive ecosystem recovery can provide new insights to support decision-making concerning intertidal habitat restoration.

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“…Due to our rapidly warming climate, increasing attention is being paid to the future fate of salt marsh vegetation and the stability of marshes themselves (Bakker et al 1993;Bertness et al 2002;Feagin et al 2010;Kim et al 2011a;Kirwan et al 2010;Reed 1995). This warming trend induces the thermal expansion of oceans and the melting of polar and alpine ice, causing the mean sea level to rise along many coastlines worldwide.…”

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confidence: 99%

Modeling the long-term vegetation dynamics of a backbarrier salt marsh in the Danish Wadden Sea

Kim

2023

J Ecol Environ

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Background: Over the past three decades, gradual eustatic sea-level rise has been considered a primary exogenous factor in the increased frequency of flooding and biological changes in several salt marshes. Under this paradigm, the potential importance of shortterm events, such as ocean storminess, in coastal hydrology and ecology is underrepresented in the literature. In this study, a simulation was developed to evaluate the influence of wind waves driven by atmospheric oscillations on sedimentary and vegetation dynamics at the Skallingen salt marsh in southwestern Denmark. The model was built based on long-term data of mean sea level, sediment accretion, and plant species composition collected at the Skallingen salt marsh from 1933-2006. In the model, the submergence frequency (number yr -1 ) was estimated as a combined function of wind-driven high water level (HWL) events (> 80 cm Danish Ordnance Datum) affected by the North Atlantic Oscillation (NAO) and changes in surface elevation (cm yr -1 ). Vegetation dynamics were represented as transitions between successional stages controlled by flooding effects. Two types of simulations were performed: (1) baseline modeling, which assumed no effect of wind-driven sea-level change, and (2) experimental modeling, which considered both normal tidal activity and wind-driven sea-level change. Results: Experimental modeling successfully represented the patterns of vegetation change observed in the field. It realistically simulated a retarded or retrogressive successional state dominated by early-to mid-successional species, despite a continuous increase in surface elevation at Skallingen. This situation is believed to be caused by an increase in extreme HWL events that cannot occur without meteorological ocean storms. In contrast, baseline modeling showed progressive succession towards the predominance of late-successional species, which was not the then-current state in the marsh. Conclusions: These findings support the hypothesis that variations in the NAO index toward its positive phase have increased storminess and wind tides on the North Sea surface (especially since the 1980s). This led to an increased frequency and duration of submergence and delayed ecological succession. Researchers should therefore employ a multitemporal perspective, recognizing the importance of short-term sea-level changes nested within long-term gradual trends.

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Salt Marshes as Potential Indicators of Global Climate Change

Cited by 12 publications

References 94 publications

Salt Marsh Bacterial Communities before and after the Deepwater Horizon Oil Spill

Salt Marsh Bacterial Communities before and after the Deepwater Horizon Oil Spill

The impacts of land-use changes on the recovery of saltmarshes in Portugal

Modeling the long-term vegetation dynamics of a backbarrier salt marsh in the Danish Wadden Sea

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