Seasonal Variation of Virioplankton in a Eutrophic Shallow Lake

Liu, Yanming; Zhang, Qi-Ya; Yuan, Xing; Li, Zhengqiu; Gui, Jian‐Fang

doi:10.1007/s10750-005-1280-4

Cited by 18 publications

(12 citation statements)

References 31 publications

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“…The VPR values observed here were slightly higher than the average range described for continental environments (20-25;Maranger & Bird, 1995;Wommack & Colwell, 2000), and possibly similar to those reported in some systems with mesotrophic to eutrophic conditions, where a strong viral control has been attributed by a high rate of contact between viral particles and hosts (Bettarel et al, 2003;Weinbauer, 2004;Liu et al, 2006;Almeida et al, 2015). Thus, the trophic status or sporadic events of enrichment may promote the growth rates and/or the increase in biovolume of the host cell community, which in turn influence positively the assembly of viral particles and the burst size (Weinbauer & Höfle, 1998;Middelboe, 2000;Choi et al, 2003).…”

Section: Discussionsupporting

confidence: 84%

“…The VLP values from El Neusa reservoir were within the same order of magnitude as those observed in lentic ecosystems of temperate and tropical latitudes with different trophic states, especially those with moderate to high levels of nutrients and biological productivity (Wilhelm & Smith, 2000;Bettarel et al, 2003;Liu et al, 2006;De Araújo & Godinho, 2009;Ram et al, 2011;Hardbower et al, 2012;Almeida et al, 2015). However, the variability of this study was relatively higher than in other studies, probably due to differences in temporal and spatial scales of the sampling design.…”

Section: Discussionsupporting

confidence: 69%

See 1 more Smart Citation

Spatial and temporal dynamics of virioplankton in a high mountain tropical reservoir, El Neusa (Cundinamarca, Colombia)

Hakspiel-Segura¹,

Rosso-Londoño²,

Canosa-Torrado

et al. 2017

lajar

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Section: Discussionsupporting

confidence: 84%

Section: Discussionsupporting

confidence: 69%

Spatial and temporal dynamics of virioplankton in a high mountain tropical reservoir, El Neusa (Cundinamarca, Colombia)

Hakspiel-Segura¹,

Rosso-Londoño²,

Canosa-Torrado

et al. 2017

lajar

View full text Add to dashboard Cite

“…Virus densities are typically lower under ice and during the winter months (Liu et al 2006) but in some cases are equivalent to virus densities reported in warmer seasons (Filippini et al 2008;Lymer et al 2008;Wilhelm and Matteson 2008). Some studies have found that the virus to bacteria ratio can even be higher in winter than in summer (Filippini et al 2008).…”

Section: Mortality Factorsmentioning

confidence: 78%

The under‐ice microbiome of seasonally frozen lakes

Bertilsson

Burgin

Carey

et al. 2013

Limnology & Oceanography

170

207

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Compared to the well-studied open water of the ''growing'' season, under-ice conditions in lakes are characterized by low and rather constant temperature, slow water movements, limited light availability, and reduced exchange with the surrounding landscape. These conditions interact with ice-cover duration to shape microbial processes in temperate lakes and ultimately influence the phenology of community and ecosystem processes. We review the current knowledge on microorganisms in seasonally frozen lakes. Specifically, we highlight how under-ice conditions alter lake physics and the ways that this can affect the distribution and metabolism of auto-and heterotrophic microorganisms. We identify functional traits that we hypothesize are important for understanding under-ice dynamics and discuss how these traits influence species interactions. As ice coverage duration has already been seen to reduce as air temperatures have warmed, the dynamics of the underice microbiome are important for understanding and predicting the dynamics and functioning of seasonally frozen lakes in the near future.The quality of freshwater, which is tightly tied to many essential ecosystem services, is influenced in large part by the activities of microbial communities. In inland waters, as in other ecosystems, microorganisms are at the hub of most biogeochemical processes and largely control ecosystem functioning via their metabolic activities. However, attempts to describe the taxonomy and ecology of the freshwater microbiome mainly involve samples collected during the icefree season and, hence, largely neglect microbial communities and their activities during the ice-covered period. Knowledge about the year-round ecological and biogeochemical traits of typical freshwater microorganisms is required to understand when and where certain microorganisms will appear and how they will influence other organisms or biogeochemical processes and, hence, water quality. Together, this information will improve our ability to predict and model freshwater ecosystem and biogeochemical dynamics and to determine their role in the landscapes in the face of environmental change.A large number of lakes, particularly those situated at high altitude and the numerous high-latitude lakes in the temperate and boreal climate zones, are seasonally covered by ice for more than 40% of the year (Walsh et al. 1998). Despite this, surprisingly little is known about the ecology, diversity, and metabolism of microorganisms that reside under the ice cover in such lakes (Salonen et al. 2009). The traditional view is that ecosystems subjected to low temperatures are ''on hold'' and that cellular adaptations for survival at low temperatures control the composition of the winter microbial community, which awaits environmental conditions more conducive for growth. This traditional concept fails to recognize that the winter season affects the ecology and metabolic features of freshwater microorganisms, as well as their involvement in food webs and global biogeochemical c...

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“…While several studies have found viral abundance in freshwater lakes to be strongly correlated to chl a levels (Madan et al 2005, Liu et al 2006, Tijdens et al 2008, other studies have found viral abundance in certain lakes (Personnic et al 2009, Cheng et al 2010) and many marine systems (Maranger & Bird 1995) to be significantly correlated with bacterial abundance. These differences could indicate differences in the dominance of certain types of virioplankton (bacteriophages vs. cyanophages or algal viruses, for example) among different ecosystems.…”

Section: Abundancementioning

confidence: 96%