Polychaete mucopolysaccharide alters sediment microbial diversity and stimulates ammonia-oxidising functional groups
Polychaete mucopolysaccharide alters sediment microbial diversity and stimulates ammonia-oxidising functional groups
Sediment nitrogen cycling is a network of microbially mediated biogeochemical processes that are vital in regulating ecosystem functioning. Mucopolysaccharides (mucus) are produced by many invertebrates and have the potential to be an important source of organic carbon and nitrogen to sediment microorganisms. At present, we have limited understanding of how mucopolysaccharide moderates total sediment microbial communities and specific microbial functional groups that drive nitrogen cycling processes. To start addressing this knowledge gap, sediment slurries were incubated with and without Hediste diversicolor mucus. Changes in dissolved inorganic nitrogen (ammonia, nitrite and nitrate) concentrations and bacterial and archaeal community diversity were assessed. Our results showed that mucopolysaccharide addition supported a more abundant and distinct microbial community. Moreover, mucus stimulated the growth of bacterial and archaeal ammonia oxidisers, with a concomitant increase in nitrite and nitrate. Hediste diversicolor mucopolysaccharide appears to enhance sediment nitrification rates by stimulating and fuelling nitrifying microbial groups. We propose that invertebrate mucopolysaccharide secretion should be considered as a distinct functional trait when assessing invertebrate contributions to sediment ecosystem function. By including this additional trait, we can improve our mechanistic understanding of invertebrate-microbe interactions in nitrogen transformation processes and provide opportunity to generate more accurate models of global nitrogen cycling.
1-10
Dale, Harriet
ccee5d44-1ea6-4712-bffe-deb08aa3904a
Taylor, Joe D.
c255b314-25d7-4d35-8aa6-e7c56e1fbdcb
Solan, Martin
c28b294a-1db6-4677-8eab-bd8d6221fecf
Lam, Phyllis
996aef80-a15d-4827-aed8-1b97b378f6ad
Cunliffe, Michael
ceabbc1b-009e-480d-b111-52ad6592855b
1 February 2019
Dale, Harriet
ccee5d44-1ea6-4712-bffe-deb08aa3904a
Taylor, Joe D.
c255b314-25d7-4d35-8aa6-e7c56e1fbdcb
Solan, Martin
c28b294a-1db6-4677-8eab-bd8d6221fecf
Lam, Phyllis
996aef80-a15d-4827-aed8-1b97b378f6ad
Cunliffe, Michael
ceabbc1b-009e-480d-b111-52ad6592855b
Dale, Harriet, Taylor, Joe D., Solan, Martin, Lam, Phyllis and Cunliffe, Michael
(2019)
Polychaete mucopolysaccharide alters sediment microbial diversity and stimulates ammonia-oxidising functional groups.
FEMS Microbiology Ecology, 95 (2), .
(doi:10.1093/femsec/fiy234).
Abstract
Sediment nitrogen cycling is a network of microbially mediated biogeochemical processes that are vital in regulating ecosystem functioning. Mucopolysaccharides (mucus) are produced by many invertebrates and have the potential to be an important source of organic carbon and nitrogen to sediment microorganisms. At present, we have limited understanding of how mucopolysaccharide moderates total sediment microbial communities and specific microbial functional groups that drive nitrogen cycling processes. To start addressing this knowledge gap, sediment slurries were incubated with and without Hediste diversicolor mucus. Changes in dissolved inorganic nitrogen (ammonia, nitrite and nitrate) concentrations and bacterial and archaeal community diversity were assessed. Our results showed that mucopolysaccharide addition supported a more abundant and distinct microbial community. Moreover, mucus stimulated the growth of bacterial and archaeal ammonia oxidisers, with a concomitant increase in nitrite and nitrate. Hediste diversicolor mucopolysaccharide appears to enhance sediment nitrification rates by stimulating and fuelling nitrifying microbial groups. We propose that invertebrate mucopolysaccharide secretion should be considered as a distinct functional trait when assessing invertebrate contributions to sediment ecosystem function. By including this additional trait, we can improve our mechanistic understanding of invertebrate-microbe interactions in nitrogen transformation processes and provide opportunity to generate more accurate models of global nitrogen cycling.
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Accepted/In Press date: 12 December 2018
e-pub ahead of print date: 14 December 2018
Published date: 1 February 2019
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Local EPrints ID: 428965
URI: http://eprints.soton.ac.uk/id/eprint/428965
PURE UUID: c7faaea9-8b01-4994-ad90-690be4cb6dde
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Date deposited: 15 Mar 2019 17:30
Last modified: 16 Mar 2024 04:16
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Author:
Harriet Dale
Author:
Joe D. Taylor
Author:
Michael Cunliffe
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