Species-specific ingestion of organic carbon by deep-sea benthic foraminifera and meiobenthos: In situ tracer experiments

Nomaki, Hidetaka; Heinz, Petra; Nakatsuka, Takeshi; Shimanaga, Motohiro; Kitazato, Hiroshi

doi:10.4319/lo.2005.50.1.0134

Cited by 113 publications

(101 citation statements)

References 34 publications

(50 reference statements)

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“…Niche separation between different surface-sediment feeding foraminiferans is demonstrated by the composition of algal pigments in the cytoplasm, confirming previous experimental results (Heinz et al, 2001;Nomaki et al, 2005Nomaki et al, , 2009Witte et al, 2003). The high ratios of chlorophyll a and Pheo a pigments in Miliolinella 1 and Miliolinella 2 shows that they were feeding on fresh phytodetritus.…”

Section: Discussionsupporting

confidence: 75%

“…But it has also been shown that many deep-sea foraminiferans are associated with phytodetrital aggregates (Cornelius and Gooday, 2004) and can give a fast response to pulses of phytodetritus (Gooday, 1988(Gooday, , 2002. The response of foraminiferans to phytodetritus exposure has been extensively documented both in situ and experimentally (Enge et al, 2011;Heinz et al, 2001;Nomaki et al, 2005Nomaki et al, , 2009Witte et al, 2003). Indirectly, the distribution of benthic foraminiferal faunas, e.g., dominated by Epistominella exigua (Brady, 1884) in various Southern Ocean environments are a reflection of the importance of phytodetritus pulses (Mackensen et al, 1993(Mackensen et al, , 1995.…”

Section: Introductionmentioning

confidence: 99%

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Algal pigments in Southern Ocean abyssal foraminiferans indicate pelagobenthic coupling

Cedhagen

Cheah

Bracher

et al. 2014

Deep Sea Research Part II: Topical Studies in Oceanography

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a b s t r a c tThe cytoplasm of four species of abyssal benthic foraminiferans from the Southern Ocean (around 511S; 121W and 501S; 391W) was analysed by High Performance Liquid Chromatography (HPLC) and found to contain large concentrations of algal pigments and their degradation products. The composition of the algal pigments in the foraminiferan cytoplasm reflected the plankton community at the surface. Some foraminiferans contained high ratios of chlorophyll a/degraded pigments because they were feeding on fresher phytodetritus. Other foraminiferans contained only degraded pigments which shows that they utilized degraded phytodetritus. The concentration of algal pigment and corresponding degradation products in the foraminiferan cytoplasm is much higher than in the surrounding sediment. It shows that the foraminiferans collect a diluted and sparse food resource and concentrate it as they build up their cytoplasm. This ability contributes to the understanding of the great quantitative success of foraminiferans in the deep sea. Benthic foraminiferans are a food source for many abyssal metazoans. They form a link between the degraded food resources, phytodetritus, back to the active metazoan food chains.

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Section: Discussionsupporting

confidence: 75%

Section: Introductionmentioning

confidence: 99%

Algal pigments in Southern Ocean abyssal foraminiferans indicate pelagobenthic coupling

Cedhagen

Cheah

Bracher

et al. 2014

Deep Sea Research Part II: Topical Studies in Oceanography

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“…In situ experiments at a mildly oxygen-depleted bathyal site in Sagami Bay, Japan (1450 m depth) suggest that broad differences exist in the trophic preferences of different deep-sea foraminiferal species, as well as the degree to which they respond to pulses of labile food. Thus, some species (including Uvigerina akitaensis) in Sagami Bay consume only fresh algae and are particularly active in the short-term processing of algal-derived organic matter, while others will ingest sedimentary organic matter as well as more labile material (Nomaki et al, 2005a(Nomaki et al, , 2006(Nomaki et al, , 2011. Subsequent experiments in which labelled carbon was tracked into specific fatty acids within foraminiferal cells suggested that some species (again including U. akitinensis) are able to degrade and/or synthesise some fatty acids (Nomaki et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Uptake of algal carbon and the likely synthesis of an "essential" fatty acid by Uvigerina ex. gr. semiornata (Foraminifera) within the Pakistan margin oxygen minimum zone: evidence from fatty acid biomarker and 13C tracer experiments

et al. 2014

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Abstract. Foraminifera are an important component of benthic communities in oxygen-depleted settings, where they potentially play a significant role in the processing of organic matter. We tracked the uptake of a 13 C-labelled algal food source into individual fatty acids in the benthic foraminiferal species Uvigerina ex. gr. semiornata from the Arabian Sea oxygen minimum zone (OMZ). The tracer experiments were conducted on the Pakistan margin during the late/post monsoon period (August-October 2003). A monoculture of the diatom Thalassiosira weisflogii was 13 C-labelled and used to simulate a pulse of phytoplankton in two complementary experiments. A lander system was used for in situ incubations at 140 m water depth and for 2.5 days in duration. Shipboard laboratory incubations of cores collected at 140 m incorporated an oxystat system to maintain ambient dissolved oxygen concentrations and were terminated after 5 days. Uptake of diatoms was rapid, with a high incorporation of diatom fatty acids into foraminifera after ∼ 2 days in both experiments. Ingestion of the diatom food source was indicated by the increase over time in the quantity of diatom biomarker fatty acids in the foraminifera and by the high percentage of 13 C in many of the fatty acids present at the endpoint of both in situ and laboratory-based experiments. These results indicate that U . ex. gr. semiornata rapidly ingested the diatom food source and that these foraminifera will play an important role in the short-term cycling of organic matter within this OMZ environment.

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“…The experiment was performed on the seafloor at the central part of Sagami Bay, Japan (3500.8'N, 13921.6'E; 1453 m depth) 17 for 0-405 days (Supplementary Figure 1). 50…”

mentioning

confidence: 99%

Sedimentary membrane lipids recycled by deep-sea benthic archaea

et al. 2010

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Deep-sea sediments harbour a vast biosphere. Archaea—one of the three domains of life1—are prevalent in marine environments2, 3, 4, 5, and comprise a significant fraction of the biomass in marine sediments6. Archaeal membranes are well characterized, and are comprised of a glycerol backbone and a nonpolar isoprenoid chain. However, the ecology of sedimentary archaea remains elusive, because it is difficult to grow them in the laboratory. Here, we trace the fate of 13C-labelled glucose added to marine sediments in Sagami Bay, Japan, to determine the in situ mechanisms of membrane synthesis. Following the addition of labelled glucose to sediment samples collected in the region, we placed the cores on the sea floor and sampled them after 9 and 405 days. We found that the 13C was incorporated into the glycerol backbone of archaeal membranes; 13C was apparent after 9 days of incubation, but most pronounced after 405 days. However, the isoprenoid chain of the membranes remained unlabelled. On the basis of the differential uptake of 13C, we suggest that the glycerol unit is synthesized de novo, whereas the isoprenoid unit is synthesized from relic archaeal membranes and detritus, because of the prevalence of these compounds in marine sediments. We therefore suggest that some benthic archaea build their membranes by recycling sedimentary organic compounds

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Species-specific ingestion of organic carbon by deep-sea benthic foraminifera and meiobenthos: In situ tracer experiments

Cited by 113 publications

References 34 publications

Algal pigments in Southern Ocean abyssal foraminiferans indicate pelagobenthic coupling

Algal pigments in Southern Ocean abyssal foraminiferans indicate pelagobenthic coupling

Uptake of algal carbon and the likely synthesis of an "essential" fatty acid by <i>Uvigerina</i> ex. gr. <i>semiornata</i> (Foraminifera) within the Pakistan margin oxygen minimum zone: evidence from fatty acid biomarker and <sup>13</sup>C tracer experiments

Sedimentary membrane lipids recycled by deep-sea benthic archaea

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