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1. Pulsed inputs of high molecular weight organic matter shift the mechanisms of substrate utilisation in marine bacterial communities

   https://doi.org/10.1111/1462-2920.16580  

   Brown, Sarah; Lloyd, C Chad; Giljan, Greta; Ghobrial, Sherif; Amann, Rudolf; Arnosti, Carol (February 2024, Environmental Microbiology)

   Abstract Heterotrophic bacteria hydrolyze high molecular weight (HMW) organic matter extracellularly prior to uptake, resulting in diffusive loss of hydrolysis products. An alternative ‘selfish’ uptake mechanism that minimises this loss has recently been found to be common in the ocean. We investigated how HMW organic matter addition affects these two processing mechanisms in surface and bottom waters at three stations in the North Atlantic Ocean. A pulse of HMW organic matter increased cell numbers, as well as the rate and spectrum of extracellular enzymatic activities at both depths. The effects on selfish uptake were more differentiated: in Gulf Stream surface waters and productive surface waters south of Newfoundland, selfish uptake of structurally simple polysaccharides increased upon HMW organic matter addition. The number of selfish bacteria taking up structurally complex polysaccharides, however, was largely unchanged. In contrast, in the oligotrophic North Atlantic gyre, despite high external hydrolysis rates, the number of selfish bacteria was unchanged, irrespective of polysaccharide structure. In deep bottom waters (> 4000 m), structurally complex substrates were processed only by selfish bacteria. Mechanisms of substrate processing—and the extent to which hydrolysis products are released to the external environment—depend on substrate structural complexity and the resident bacterial community. 

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2. Selfish bacteria are active throughout the water column of the ocean

   https://doi.org/10.1038/s43705-023-00219-7  

   Giljan, Greta; Brown, Sarah; Lloyd, C. Chad; Ghobrial, Sherif; Amann, Rudolf; Arnosti, Carol (December 2023, ISME Communications)

   Abstract Heterotrophic bacteria in the ocean invest carbon, nitrogen, and energy in extracellular enzymes to hydrolyze large substrates to smaller sizes suitable for uptake. Since hydrolysis products produced outside of a cell may be lost to diffusion, the return on this investment is uncertain. Selfish bacteria change the odds in their favor by binding, partially hydrolyzing, and transporting polysaccharides into the periplasmic space without loss of hydrolysis products. We expected selfish bacteria to be most common in the upper ocean, where phytoplankton produce abundant fresh organic matter, including complex polysaccharides. We, therefore, sampled water in the western North Atlantic Ocean at four depths from three stations differing in physiochemical conditions; these stations and depths also differed considerably in microbial community composition. To our surprise, we found that selfish bacteria are common throughout the water column of the ocean, including at depths greater than 5500 m. Selfish uptake as a strategy thus appears to be geographically—and phylogenetically—widespread. Since processing and uptake of polysaccharides require enzymes that are highly sensitive to substrate structure, the activities of these bacteria might not be reflected by measurements relying on uptake only of low molecular weight substrates. Moreover, even at the bottom of the ocean, the supply of structurally-intact polysaccharides, and therefore the return on enzymatic investment, must be sufficient to maintain these organisms. 

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3. Selfish bacteria take up polysaccharides under deep ocean pressure: insights from in-situ and ex-situ measurements

   https://doi.org/10.1093/ismeco/ycag138  

   Chad_Lloyd, C; Pareigis, Laura; Balmonte, John Paul; Glud, Ronnie N; Reintjes, Greta; Arnosti, Carol (May 2026, ISME Communications)

   Abstract Heterotrophic bacteria process a large fraction of the polysaccharides produced by phytoplankton in the surface ocean. Some of these polysaccharides are taken up by “selfish” bacteria, which bind, partially hydrolyze, and transport large fragments of polysaccharides into the cell with little loss of hydrolysis products. Recently, selfish bacteria have also been identified in deep ocean water. Whether these bacteria effectively capture polysaccharides under hydrostatic pressures typical of the deep ocean, however, remained an open question. Here, for the first time, we measured the extent of selfish uptake of laminarin—a common marine polysaccharide—in surface and deep waters, under pressures ranging from atmospheric up to ~50 MPa (equivalent to 5000 m depth). We incubated seawater from Japan, Denmark, and the western North Atlantic Ocean in pressure vessels and found that the extent of selfish uptake of laminarin varied somewhat by site but was insensitive to hydrostatic pressure. Deployment of an in situ incubator in the North Atlantic Ocean also showed evidence of selfish uptake in situ. These results suggest that selfish uptake can play a key role in polysaccharide degradation, especially in the deep ocean where other modes of organic matter degradation may be more inhibited by high hydrostatic pressure. 

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4. Carbohydrates, enzyme activities, and microbial communities across depth gradients in the western North Atlantic Ocean

   https://doi.org/10.5194/bg-22-5787-2025  

   Lloyd, C Chad; Brown, Sarah; Giljan, Greta; Ghobrial, Sherif; Vidal-Melgosa, Silvia; Steinke, Nicola; Hehemann, Jan-Hendrik; Amann, Rudolf; Arnosti, Carol (January 2025, Biogeosciences)

   Abstract. Heterotrophic bacteria process nearly half of the organic matter produced by phytoplankton in the surface ocean. Much of this organic matter consists of high-molecular-weight (HMW) biopolymers such as polysaccharides and proteins, which must initially be hydrolyzed to smaller sizes by structurally specific extracellular enzymes. Few previous studies, however, have investigated the structural complexity of polysaccharides among regions and depths. To simultaneously investigate substrate structure and microbial community composition and function, we concurrently determined carbohydrate abundance and structural complexity, bacterial community composition, and peptidase and polysaccharide hydrolase activities across depth gradients from surface to bottom water at four distinct stations in the western North Atlantic Ocean. Although the monosaccharide constituents of particulate organic matter (POM) were similar among stations, the structural complexity of POM-derived polysaccharides varied by depth and station, as demonstrated by polysaccharide-specific antibody probing. Bacterial community composition and polysaccharide hydrolase activities also varied substantially by depth, suggesting that the structure and function of bacterial communities may be related to substrate structural complexity. Thus, the extent to which bacteria can transform organic matter in the ocean is dependent on both the structural complexity of the organic matter and their enzymatic capabilities in different depths and regions of the ocean. 

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5. Linking lifestyle and foraging strategies of marine bacteria: selfish behaviour of particle‐attached bacteria in the northern Adriatic Sea

   https://doi.org/10.1111/1758-2229.13059  

   Manna, Vincenzo; Zoccarato, Luca; Banchi, Elisa; Arnosti, Carol; Grossart, Hans‐Peter; Celussi, Mauro (April 2022, Environmental Microbiology Reports)

   Microbe-mediated enzymatic hydrolysis of organic matter entails the production of hydrolysate, the recovery of which may be more or less efficient. The selfish uptake mechanism, recently discovered, allows microbes to hydrolyze polysaccharides and take up large oligomers, which are then degraded in the periplasmic space. By minimizing the hydrolysate loss, selfish behaviour may be profitable for free-living cells dwelling in a patchy substrate landscape. However, selfish uptake seems to be tailored to algal-derived polysaccharides, abundant in organic particles, suggesting that particle-attached microbes may use this strategy. We tracked selfish polysaccharides uptake in surface microbial communities of the northeastern Mediterranean Sea, linking the occurrence of this processing mode with microbial lifestyle. Additionally, we set up fluorescently labelled polysaccharides incubations supplying phytodetritus to investigate a ‘pioneer’ scenario for particle-attached microbes. Under both conditions, selfish behaviour was almost exclusively carried out by particle-attached microbes, suggesting that this mechanism may represent an advantage in the race for particle exploitation. Our findings shed light on the selfish potential of particle-attached microbes, suggesting multifaceted foraging strategies exerted by particle colonizers. 

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