Intense photooxidative degradation of planktonic and bacterial lipids in sinking particles collected with sediment traps across the Canadian Beaufort Shelf (Arctic Ocean)

Rontani, J.‐F.; Charrìère, Bruno; Forest, Alexandre; Heussner, Serge; Vaultier, Frédéric; Petit, Morgan; Delsaut, N.; Fortier, Louis; Sempéré, Richard

doi:10.5194/bg-9-4787-2012

Cited by 57 publications

(50 citation statements)

References 77 publications

(82 reference statements)

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“…Singlet oxygen transfer from the phytodetritus to attached heterotrophic bacteria could induce strong oxidative damage in these organisms (not only on unsaturated fatty acids but also on proteins and nucleic acids [57,58]), which has the potential to limit their growth and therefore contribute to a better preservation of algal organic matter during the sedimentation. Note that the surprising recalcitrance of phytodetritus towards biodegradation processes observed during the Arctic midnight sun period was recently attributed to the strong photodegradation state of heterotrophic bacteria associated with this material [33], which likely resulted from the efficient transfer of singlet oxygen from the photodegraded phytoplanktonic cells to the attached bacteria.…”

Section: Discussionmentioning

confidence: 99%

“…The present study focuses on the effects of a natural source of 1 O 2 (senescent phytoplanktonic cells) to their attached bacteria. These processes, which have been ignored in the literature until now, might strongly limit bacterial growth in the seawater column and, consequently, contribute to a better preservation of algal material toward biotic degradation during settling [33]. …”

Section: Introductionmentioning

confidence: 99%

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Photochemical Production and Behavior of Hydroperoxyacids in Heterotrophic Bacteria Attached to Senescent Phytoplanktonic Cells

Petit

Sempéré

Vaultier

et al. 2013

IJMS

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The photooxidation of cellular monounsaturated fatty acids was investigated in senescent phytoplanktonic cells (Emiliania huxleyi) and in their attached bacteria under laboratory controlled conditions. Our results indicated that UV-visible irradiation of phytodetritus induced the photooxidation of oleic (produced by phytoplankton and bacteria) and cis-vaccenic (specifically produced by bacteria) acids. These experiments confirmed the involvement of a substantial singlet oxygen transfer from senescent phytoplanktonic cells to attached bacteria, and revealed a significant correlation between the concentration of chlorophyll, a photosensitizer, in the phytodetritus and the photodegradation state of bacteria. Hydroperoxyacids (fatty acid photoproducts) appeared to be quickly degraded to ketoacids and hydroxyacids in bacteria and in phytoplanktonic cells. This degradation involves homolytic cleavage (most likely induced by UV and/or transition metal ions) and peroxygenase activity (yielding epoxy acids).

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Photochemical Production and Behavior of Hydroperoxyacids in Heterotrophic Bacteria Attached to Senescent Phytoplanktonic Cells

Petit

Sempéré

Vaultier

et al. 2013

IJMS

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“…While we did not observe statistically significant rates of photooxidation in monounsaturated IP-DAG, a significant body of literature has shown that MUFA-derived oxylipins (i.e., free fatty acid derivatives cleaved from their lipid headgroup) do contribute to the oxidized lipid pool in surface waters, sinking particles, and seafloor marine sediments on scales which are all environmentally relevant (Marchand and Rontani, 2001;Rontani, 1999;Rontani et al, 2016;Rontani et al, 2012a;Rontani et al, 2012b). In Antarctic waters specifically, there is reason to presume that oxidation and removal of certain lipids at the ocean's surface could affect the quality of the lipid biomass that is exported to depth.…”

Section: Conclusion and Additional Biogeochemical Implicationsmentioning

confidence: 63%

“…While lipid peroxidation has been implicated in studies of UVR stress in Antarctic organisms and ecosystems, it has to our knowledge never been characterized at the molecular level, nor its significance explored at the ecosystem scale in the Antarctic. Groundbreaking work by Rontani and others (Christodoulou et al, 2010;Marchand and Rontani, 2001;Rontani, 1999;2001;Rontani et al, 1998;Rontani et al, 2016;Rontani et al, 2012a;Rontani et al, 2012b) has established that the photooxidation of mono-and di-unsaturated fatty acids in surface ocean biomass is a process significant enough to be detected via certain short-chain oxylipin biomarkers in sinking marine particulate material. Rontani and others have used these biomarkers to make estimates of the overall photooxidation state of the organic matter present in these particles, but there are virtually no estimates at the ecosystem scale of the rate at which organic matter in the surface ocean can be degraded via lipid photooxidation compared with many other processes that contribute to remineralization.…”

Section: Uvr-induced Oxylipin Production Via Ros Has Been Extensivelymentioning

confidence: 99%

The remineralization of marine organic matter by diverse biological and abiotic processes

Collins¹

2017

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While aerobic respiration is typically invoked as the dominant mass-balance sink for organic matter in the upper ocean, many other biological and abiotic processes can degrade particulate and dissolved substrates on globally significant scales. The relative strengths of these other remineralization processes -including mechanical mechanisms such as dissolution and disaggregation of sinking particles, and abiotic processes such as photooxidation -remain poorly constrained. In this thesis, I examine the biogeochemical significance of various alternative pathways of organic matter remineralization using a combination of field experiments, modeling approaches, geochemical analyses, and a new, high-throughput lipidomics method for identification of lipid biomarkers. I first assess the relative importance of particleattached microbial respiration compared to other processes that can degrade sinking marine particles. A hybrid methodological approach -comparison of substrate-specific respiration rates from across the North Atlantic basin with Monte Carlo-style sensitivity analyses of a simple mechanistic model -suggested sinking particle material was transferred to the water column by various biological and mechanical processes nearly 3.5 times as fast as it was directly respired, questioning the conventional assumption that direct respiration dominates remineralization. I next present and demonstrate a new lipidomics method and open-source software package for discovery and identification of molecular biomarkers for organic matter degradation in large, high-mass-accuracy HPLC-ESI-MS datasets. I use the software to unambiguously identify more than 1,100 unique lipids, oxidized lipids, and oxylipins in data from cultures of the marine diatom Phaeodactylum tricornutum that were subjected to oxidative stress. Finally, I present the results of photooxidation experiments conducted with liposomes -nonliving aggregations of lipids -in natural waters of the Southern Ocean. A broadband polychromatic apparent quantum yield (AQY) is applied to estimate rates of lipid photooxidation in surface waters of the West Antarctic Peninsula, which receive seasonally elevated doses of ultraviolet radiation as a consequence of anthropogenic ozone depletion in the stratosphere. The mean daily rate of lipid photooxidation (50 ± 11 pmol IP-DAG L −1 d −1 , equivalent to 31 ± 7 g C m −3 d −1 ) represented between 2 and 8 % of the total bacterial production observed in surface waters immediately following the retreat of the sea ice. AcknowledgmentsModern science is a highly collaborative enterprise. And yet -at times -it can be incredibly isolating. A great number of people have nurtured, challenged, and supported me scientifically and emotionally over the past five and a half years as I have operated at fits and starts in each of these modes of scientific inquiry. While I've thanked many of these individuals in these Acknowledgments and in the acknowledgments sections of my separate thesis chapters, I am sure I've committed the sin of omi...

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“…These authors suggested that extracellular H 2 O 2 could be a common byproduct of biological processes (as is intracellular H 2 O 2 ), or a product of a specific biochemical process, indicating that H 2 O 2 production rates might vary with environmental factors and species composition. Interestingly, it was recently hypothesized that abiotic processes such as photoxidation are able to produce peroxides (i.e., hydroperoxides associated with organic matter) that might inhibit bacterial activity by singlet oxygen transfer from phytodetritus to particle-attached bacteria [15]. The oxidative stress provoked by such particle-associated production of reactive oxygen species could be particularly relevant in microhabitats and in the deep ocean due to the preferential particle-related life strategy of dark ocean prokaryotes [16], [17], [18], [19].…”

Section: Introductionmentioning

confidence: 99%

Major Effect of Hydrogen Peroxide on Bacterioplankton Metabolism in the Northeast Atlantic

et al. 2013

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Reactive oxygen species such as hydrogen peroxide have the potential to alter metabolic rates of marine prokaryotes, ultimately impacting the cycling and bioavailability of nutrients and carbon. We studied the influence of H2O2 on prokaryotic heterotrophic production (PHP) and extracellular enzymatic activities (i.e., β-glucosidase [BGase], leucine aminopeptidase [LAPase] and alkaline phosphatase [APase]) in the subtropical Atlantic. With increasing concentrations of H2O2 in the range of 100–1000 nM, LAPase, APase and BGase were reduced by up to 11, 23 and 62%, respectively, in the different water layers. Incubation experiments with subsurface waters revealed a strong inhibition of all measured enzymatic activities upon H2O2 amendments in the range of 10–500 nM after 24 h. H2O2 additions also reduced prokaryotic heterotrophic production by 36–100% compared to the rapid increases in production rates occurring in the unamended controls. Our results indicate that oxidative stress caused by H2O2 affects prokaryotic growth and hydrolysis of specific components of the organic matter pool. Thus, we suggest that oxidative stress may have important consequences on marine carbon and energy fluxes.

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Intense photooxidative degradation of planktonic and bacterial lipids in sinking particles collected with sediment traps across the Canadian Beaufort Shelf (Arctic Ocean)

Cited by 57 publications

References 77 publications

Photochemical Production and Behavior of Hydroperoxyacids in Heterotrophic Bacteria Attached to Senescent Phytoplanktonic Cells

Photochemical Production and Behavior of Hydroperoxyacids in Heterotrophic Bacteria Attached to Senescent Phytoplanktonic Cells

The remineralization of marine organic matter by diverse biological and abiotic processes

Major Effect of Hydrogen Peroxide on Bacterioplankton Metabolism in the Northeast Atlantic

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