INRA, UMR 042 CARRTEL, 75 Avenue de Corzent, 74203, Thonon-les-Bains cx, France.
Microb Ecol. 2014 Jan;67(1):66-82. doi: 10.1007/s00248-013-0320-2. Epub 2013 Nov 20.
We sampled the surface waters (2-50 m) of two deep peri-alpine lakes over a 1-year period in order to examine (1) the abundance, vertical distribution, genome size, and morphology structures of the virioplankton; (2) the virus-mediated bacterial mortality; and (3) the specific genome size range of double-stranded DNA (dsDNA) phytoplankton viruses. Virus-like particle (VLP) concentrations varied between 4.16 × 10(7) (January) and 2.08 × 10(8) part mL(-1) (May) in Lake Bourget and between 2.7 × 10(7) (June) and 8.39 × 10(7) part mL(-1) (November) in Lake Annecy. Our flow cytometry analysis revealed at least three viral groups (referred to as virus-like particles 1, 2, and 3) that exhibited distinctive dynamics suggestive of different host types. Phage-induced bacterial mortality varied between 6.1% (June) and 33.2% (October) in Lake Bourget and between 7.4% (June) and 52.6% (November) in Lake Annecy, suggesting that viral lysis may be a key cause of mortality of the bacterioplankton. Virioplankton genome size ranged from 27 to 486 kb in Lake Bourget, while it reached 620 kb in Lake Annecy for which larger genome sizes were recorded. Our analysis of pulsed field gel electrophoresis bands using different PCR primers targeting both cyanophages and algal viruses showed that (1) dsDNA viruses infecting phytoplankton may range from 65 to 486 kb, and (2) both cyanophage and algal "diversity" were higher in Lake Annecy. Lakes Annecy and Bourget also differed regarding the proportions of both viral families (with the dominance of myoviruses vs. podoviruses) and infected bacterial morphotypes (short rods vs. elongated rods), in each of these lakes, respectively. Overall, our results reveal that (1) viruses displayed distinct temporal and vertical distribution, dynamics, community structure in terms of genome size and morphology, and viral activity in the two lakes; (2) the Myoviridae seemed to be the main cause of bacterial mortality in both lakes and this group seemed to be related to VLP2; and (3) phytoplankton viruses may have a broader range of genome size than previously thought. This study adds to growing evidence that viruses are diverse and play a significant role in freshwater microbial dynamics and more globally lake functioning. It highlights the importance of further considering this biological compartment for a better understanding of plankton ecology in peri-alpine lakes.
我们在一年的时间内对两个深高山间湖泊的表层水(2-50 米)进行了采样,以研究:(1)病毒浮游生物的丰度、垂直分布、基因组大小和形态结构;(2)病毒介导的细菌死亡率;(3)双链 DNA(dsDNA)浮游病毒的特定基因组大小范围。在 Bourget 湖,病毒样颗粒(VLP)浓度在 4.16×10(7)(1 月)至 2.08×10(8)个 mL(-1)(5 月)之间变化,在 Annecy 湖,VLP 浓度在 2.7×10(7)(6 月)至 8.39×10(7)个 mL(-1)(11 月)之间变化。我们的流式细胞术分析显示,至少有三种病毒群(称为病毒样颗粒 1、2 和 3)表现出不同的动态,表明存在不同的宿主类型。在 Bourget 湖中,噬菌体诱导的细菌死亡率在 6.1%(6 月)至 33.2%(10 月)之间变化,在 Annecy 湖中,噬菌体诱导的细菌死亡率在 7.4%(6 月)至 52.6%(11 月)之间变化,这表明病毒裂解可能是细菌浮游生物死亡的一个关键原因。Bourget 湖的病毒浮游生物基因组大小范围为 27 至 486 kb,而 Annecy 湖的病毒浮游生物基因组大小范围为 620 kb,记录到的基因组大小更大。我们使用针对蓝藻噬菌体和藻类病毒的不同 PCR 引物对脉冲场凝胶电泳带进行的分析表明,(1)感染浮游植物的 dsDNA 病毒的大小范围可能为 65 至 486 kb,(2)在 Annecy 湖中,蓝藻噬菌体和藻类“多样性”更高。Annecy 和 Bourget 两个湖泊的病毒科(以肌病毒科为主,尾病毒科次之)和感染的细菌形态(短杆菌和长杆菌)比例也不同。总的来说,我们的研究结果表明,(1)病毒在两个湖泊中表现出不同的时间和垂直分布、动态、基因组大小和形态结构的群落结构以及病毒活性;(2)肌病毒科似乎是两个湖泊中细菌死亡率的主要原因,该组病毒似乎与 VLP2 有关;(3)浮游植物病毒的基因组大小范围可能比以前认为的更广泛。这项研究增加了越来越多的证据,即病毒具有多样性,并在淡水微生物动态和更广泛的湖泊功能中发挥着重要作用。它强调了进一步考虑这一生物区室以更好地了解高山湖泊浮游生态学的重要性。
