Viral dynamics in two trophically different areas in the Central Adriatic Sea

Ordulj, Marin; Krstulović, Nada; Šantić, Danijela; Jozić, Slaven; Šolić, Mladen

doi:10.1186/s10152-017-0502-2

Cited by 13 publications

(6 citation statements)

References 68 publications

(108 reference statements)

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“…Using the current scheme and parameters of our viral module, the model simulated viral decay rates of 13.7% ± 0.7% d −1 and 8.3% ± 0.7% d −1 in the surface and subsurface layers at HOT, respectively, while the rates were 40.6% ± 7.8% d −1 and 20.1% ± 2.9% d −1 at AS. These decay rates at AS were generally comparable to the observations of 39.4% ± 5.0% d −1 measured in the western Pacific Ocean [63], 43.9% ± 10.2% d −1 in the Central Adriatic Sea [34], 25.4% ± 8.4% d −1 in the North Sea [64] and 70.8% ± 30.1% d −1 in the South China Sea [31]. The low viral decay rates in extremely oligotrophic open oceans such as HOT can be expected because of their low productivity, but there have been no measurements reported in this kind of ocean environment.…”

Section: Discussionsupporting

confidence: 87%

“…These models, therefore, were largely similar to previous non-virus models in simulating the effects of viruses on other components of marine ecosystems, considering that most non-virus models also assigned constant mortality rates to the simulated bacteria. The viral infection rates of hosts, and subsequently the VMM rates, are highly variable [ 26 , 27 , 28 , 29 , 30 , 31 , 32 , 33 , 34 , 35 ] and can be impacted by the abundance of viruses and hosts, the temperature and nutrients [ 36 ]. As a first-order estimation, the rate of viral infection depends on the contact rate between the viruses and hosts [ 37 ] and thus can be assumed to be proportional to the product of viral and host abundances [ 38 ].…”

Section: Introductionmentioning

confidence: 99%

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Assessment of Explicit Representation of Dynamic Viral Processes in Regional Marine Ecological Models

Xie

Luo

2022

Viruses

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Viruses, the most abundant microorganisms in the ocean, play important roles in marine ecosystems, mainly by killing their hosts and contributing to nutrient recycling. However, in models simulating ecosystems in real marine environments, the virus-mediated mortality (VMM) rates of their hosts are implicitly represented by constant parameters, thus ignoring the dynamics caused by interactions between viruses and hosts. Here, we construct a model explicitly representing marine viruses and the VMM rates of major hosts, heterotrophic bacteria, and apply it to two sites in the oligotrophic North Pacific and the more productive Arabian Sea. The impacts of the viral processes were assessed by comparing model results with the viral processes enabled and disabled. For reliable assessments, a data assimilation method was used to objectively optimize the model parameters in each run. The model generated spatiotemporally variable VMM rates, generally decreasing in the subsurface but increasing at the surface. Although the dynamics introduced by viruses could be partly stabilized by the ecosystems, they still caused substantial changes to the bacterial abundance, primary production and carbon export, with the changes greater at the more productive site. Our modeling experiments reveal the importance of explicitly simulating dynamic viral processes in marine ecological models.

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Section: Discussionsupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Assessment of Explicit Representation of Dynamic Viral Processes in Regional Marine Ecological Models

Xie

Luo

2022

Viruses

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“…), nutrient availability, grazing, and viral lysis [11][12][13]. It is well-established that temperature significantly influences microbiological processes such as production [14], growth rate [15,16], and growth efficiency [17], as well as grazing on bacteria [9,18,19] and viral lysis [20][21][22][23]. However, these processes have shown different sensitivity to temperature increases, which ultimately determines how the microbial community will respond to warming [24,25].…”

Section: Introductionmentioning

confidence: 99%

Changes in the Trophic Pathways within the Microbial Food Web in the Global Warming Scenario: An Experimental Study in the Adriatic Sea

et al. 2020

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A recent analysis of the Mediterranean Sea surface temperature showed significant annual warming. Since small picoplankton microorganisms play an important role in all major biogeochemical cycles, fluxes and processes occurring in marine systems (the changes at the base of the food web) as a response to human-induced temperature increase, could be amplified through the trophic chains and could also significantly affect different aspects of the structure and functioning of marine ecosystems. In this study, manipulative laboratory growth/grazing experiments were performed under in situ simulated conditions to study the structural and functional changes within the microbial food web after a 3 °C increase in temperature. The results show that a rise in temperature affects the changes in: (1) the growth and grazing rates of picoplankton, (2) their growth efficiency, (3) carrying capacities, (4) sensitivity of their production and grazing mortality to temperature, (5) satisfying protistan grazer carbon demands, (6) their preference in the selection of prey, (7) predator niche breadth and their overlap, (8) apparent uptake rates of nutrients, and (9) carbon biomass flow through the microbial food web. Furthermore, temperature affects the autotrophic and heterotrophic components of picoplankton in different ways.

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“…Edwards and Richardson, 2004;Wiltshire et al, 2008;Montoya and Raffaelli, 2010). It is well established that temperature significantly influences microbiological processes such as production (Rivkin et al, 1996;Hoppe et al, 2008;Šoli c et al, 2018a), growth rate (White et al, 1991;Shiah and Ducklow, 1994) and growth efficiency (Rivkin and Legendre, 2001), as well as grazing on bacteria (Vaqué et al, 1994;Krstulovi c, 1994, 1995;Vázquez-Dominguez et al, 2012) and viral lysis (Danovaro et al, 2011;Lara et al, 2013;Maranger et al, 2015;Tsai et al, 2015;Ordulj et al, 2017). Furthermore, temperature influences the complex microbial trophic interactions, altering food web structure and ecosystem functioning (Petchey et al, 1999).…”

Section: Introductionmentioning

confidence: 99%

Temperature and phosphorus interacts in controlling the picoplankton carbon flux in the Adriatic Sea: an experimental versus field study

Šolić

Šantić

Šestanović

et al. 2019

Environmental Microbiology

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Temperature and phosphorus positively interacted in controlling picoplankton biomass production and its transfer towards higher trophic levels. Two complementary approaches (experimental and field study) indicated several coherent patterns: (1) the impact of temperature on heterotrophic bacteria was high at temperatures lower than 16°C and levelled off at higher temperatures, whereas this impact on autotrophic picoplankton was linear along the entire range of the investigated temperatures; (2) the addition of phosphorus increased the values of picoplankton production and grazing, but did not change the nature of their relationships with temperature substantially; (3) the picoplankton carbon flux towards higher trophic levels was larger during the warmer months (grazing by HNF dominated during the warmer period and by ciliates during the colder period) and also strengthened in conditions without phosphorus limitation; (4) the hypothesis that the available phosphorus can be better utilized at higher temperatures was confirmed for both autotrophic and heterotrophic picoplankton; (5) the hypothesis that the rise in temperature stimulates growth only in conditions of sufficient phosphorus was confirmed only for heterotrophic bacteria. Therefore, in the global warming scenario, an increase of the picoplankton carbon flux towards higher trophic levels can be expected in the Adriatic Sea, particularly under unlimited phosphorus conditions.

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Viral dynamics in two trophically different areas in the Central Adriatic Sea

Cited by 13 publications

References 68 publications

Assessment of Explicit Representation of Dynamic Viral Processes in Regional Marine Ecological Models

Assessment of Explicit Representation of Dynamic Viral Processes in Regional Marine Ecological Models

Changes in the Trophic Pathways within the Microbial Food Web in the Global Warming Scenario: An Experimental Study in the Adriatic Sea

Temperature and phosphorus interacts in controlling the picoplankton carbon flux in the Adriatic Sea: an experimental versus field study

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