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Advances in the aquatic sciences
RESEARCH ARTICLE

Microalgal sediment biostabilisation along a salinity gradient in the Eden Estuary, Scotland: unravelling a paradox

Bryan M. Spears A B C , James E. Saunders A , Irvine Davidson A and David M. Paterson A
+ Author Affiliations
- Author Affiliations

A Centre for Ecology & Hydrology Edinburgh, Penicuik, Midlothian, EH26 0QB, Scotland.

B Sediment Ecology Research Group, Gatty Marine Laboratory, University of St Andrews, Fife, KY16 8 LB, Scotland.

C Corresponding author. Email: spear@ceh.ac.uk

Marine and Freshwater Research 59(4) 313-321 https://doi.org/10.1071/MF07164
Submitted: 18 September 2007  Accepted: 28 February 2008   Published: 15 May 2008

Abstract

Microalgal biostabilisation of cohesive sediments via the production of extracellular polymeric substances (EPS) has been well documented in intertidal ecosystems and represents a key ecosystem service with respect to the regulation of sediment transport. However, recent ecosystem comparison studies have uncovered a paradox in which sediment stability is commonly observed to be lower in freshwater ecosystems (compared with estuarine ecosystems) even though sediment EPS concentrations and microalgal biomass are high. Using a combination of freshwater and estuarine field and mesocosm techniques, the relative and interactive roles of salinity and the production of EPS (carbohydrate concentration) by benthic microalgae in the mediation of sediment stability in the Eden River catchment (river, mudflat and saltmarsh) were assessed. Sediment stability apparently increased with salinity from river (42.43 N m–2 surface stagnation pressure; salinity 0) to mudflat (98.65 N m–2; salinity 25) to saltmarsh (135.48 N m–2; salinity 46). The opposite trend was observed in sediment chlorophyll a and carbohydrate concentrations, indicating that salinity is the main variable driving sediment stability across the ecosystems under moderate EPS concentrations. Observations from mesocosm experiments highlighted the individual and combined importance of salinity and EPS in biostabilisation, with the largest increase in sediment stability observed following combined additions (25-fold increase compared with the control). The biogeochemical processes responsible, and their role in buffering phosphorus transport across the freshwater–saltwater transitional zone, are discussed.

Additional keywords: ecosystem comparison, extracellular polymeric substances, sediment stability.


Acknowledgements

We appreciate the field and laboratory assistance provided by Fiona Fraser and Ruth Tomlinson. Bryan Spears and James Saunders were funded by Natural Environment Research Council, UK (NERC) PhD studentships (NER/S/A/2003/11324 and NER/S/A/2003/11890 respectively). Mesocosm work was developed with the aid of a NERC award (NER/A/S/2003/00578). We would also like to thank two anonymous reviewers and Professor Andrew Boulton for their helpful and constructive comments.


References

Calles, B. (1983). Settling processes in a saline environment. Geografiska Annaler. Series A. Physical Geography 65, 159–166.
Crossref | GoogleScholarGoogle Scholar | Decho A. W. (1994). Molecular scale events influencing the macroscale cohesiveness of exopolymers. In ‘Biostabilisation of Sediment’. (Eds W. E. Krumbein, D. M. Paterson and L. J. Stal.) pp. 135–148. (BIS Verlag: Oldenburg.)

Decho, A. W. (2000). Microbial biofilms in intertidal systems: an overview. Continental Shelf Research 20, 1257–1273.
Crossref | GoogleScholarGoogle Scholar | Flemming H.-C., Strathman M., and Morales C. F. L. (2007). Biofilms and their role in sediment dynamics and pollutant mobility. In ‘Sediment Dynamics and Pollutant Mobility in Rivers: An Interdisciplinary Approach’. (Eds B. Westrich and U. Föstner.) pp. 344–357. (Springer: Berlin, Heidelberg.)

Gerbersdorf, S. U. , Jancke, T. , and Westrich, B. (2007). A comprehensive approach to evaluate sediment properties and their covariance patterns over depth in relation to erosion resistance – First investigations in natural sediments at three contaminated reservoirs. Journal of Soils and Sediments 7, 25–35.
Crossref | GoogleScholarGoogle Scholar | HIMOM (2005). ‘Hierarchical Monitoring Methods. European Commission Fifth Framework Programme.’ Contract: EVK3-CT-2001-00052. (Brokman Consult, Geesthacht.)

Hirst, C. N. , Cyr, H. , and Jordan, I. A. (2003). Distribution of exopolymic substances in the littoral sediments of an oligotrophic lake. Microbial Ecology 46, 22–32.
Crossref | GoogleScholarGoogle Scholar | PubMed | Lerman A. (1979). ‘Geochemical Processes: Water and Sediment Environments.’ (John Wiley and Sons Publishers: New York.)

Packman, A. I. , and Jerolmack, D. (2004). The role of physicochemical processes in controlling sediment transport and deposition in turbidity currents. Marine Geology 204, 1–9.
Crossref | GoogleScholarGoogle Scholar | Pamukco S., and Tuncan M. (1991). Influence of some physicochemical activities on mechanical behavior of clays. In ‘Frontiers in Sedimentary Geology: Microstructure of Fine-grained Sediments: From Mud to Shale’. (Eds R. H. Bennet, W. R. Bryant and M. H. Hulbert.) pp. 241–253. (Springer Verlag: Berlin, Heidelberg.)

Paterson, D. M. (1989). Short-term changes in the erodibility of intertidal cohesive sediments related to the migratory behaviour of epipelic diatoms. Limnology and Oceanography 34, 223–234.
Paterson D. M. (1997). Biological mediation of sediment erodibility, ecology and physical dynamics. In ‘Cohesive Sediments’. (Eds N. Burt, R. Parker and I. Watts.) pp. 215–229. (Wiley Interscience: Chichester.)

Paterson D. M., and Black K. S. (1999). Water flow, sediment dynamics, and benthic biology. In ‘Advances in Ecological Research’. (Eds D. Raffaelii and D. Nedwell.) pp. 155–193. (Oxford University Press: Oxford.)

Perkins, R. G. , Paterson, D. M. , Sun, H. , Watson, J. , and Player, M. A. (2004). Extracellular polymeric substances: quantification and use in erosion experiments. Continental Shelf Research 24, 1623–1635.
Crossref | GoogleScholarGoogle Scholar | Spears B. M., Funnell J., Saunders J., and Paterson D. M. (2007b). On the boundaries: sediment stability measurements across aquatic ecosystems. In ‘Sediment Dynamics and Pollutant Mobility in Rivers: An Interdisciplinary Approach’. (Eds B. Westrich and U. Föstner.) pp. 68–79. (Springer: Berlin, Heidelberg.)

Sposito, G. , Skipper, N. T. , Sutton, R. , Park, S.-H. , Soper, A. K. , and Greathouse, J. A. (1999). Surface geochemistry of the clay minerals. Proceedings of the National Academy of Sciences of the United States of America 96, 3358–3364.
Crossref | GoogleScholarGoogle Scholar | PubMed | Tolhurst T. J. (1999). Microbial mediation of intertidal sediment erosion. Ph.D. Thesis. University of St Andrews.

Tolhurst, T. J. , Black, K. S. , Paterson, D. M. , Mitchener, H. , Termaat, R. , and Shayler, S. A. (2000). A comparison and measurement standardisation of four in situ devices for determining erosion sheer stress of intertidal sediments. Continental Shelf Research 20, 1397–1418.
Crossref | GoogleScholarGoogle Scholar | Townend J. (2004). ‘Practical Statistics for Environmental and Biological Scientists.’ (John Wiley and Sons: West Sussex.)

Tytler, P. , Thorpe, J. E. , and Shearer, W. M. (1978). Ultrasonic tracking of the movements of Atlantic salmon smolts (Salmo salar L) in the estuaries of two Scottish Rivers. Journal of Fish Biology 12, 575–586.
Crossref | GoogleScholarGoogle Scholar | Wetzel R. G., and Likens G. E. (2000). ‘Limnological Analyses.’ 3rd edn. (Springer-Verlag: New York.)

Wood, P. J. , and Armitage, P. D. (1997). Biological effects of fine sediment in the lotic environment. Environmental Management 21, 203–217.
Crossref | GoogleScholarGoogle Scholar | PubMed |

Yallop, M. L. , Paterson, D. M. , and Wellsbury, P. (2000). Interrelationships between rates of microbial production, exopolymer production, microbial biomass, and sediment stability in biofilms of intertidal sediments. Microbial Ecology 39, 116–127.
Crossref | GoogleScholarGoogle Scholar | PubMed |