Effect of nutrient addition and environmental factors on prophage induction in natural populations of marine synechococcus species

A series of experiments were conducted with samples collected in both Tampa Bay and the Gulf of Mexico to assess the impact of nutrient addition on cyanophage induction in natural populations of Synechococcus sp. The samples were virus reduced to decrease the background level of cyanophage and then either left untreated or amended with nitrate, ammonium, urea, or phosphate. Replicate samples were treated with mitomycin C to stimulate cyanophage induction. In five of the nine total experiments performed, cyanophage induction was present in the non-nutrient-amended control samples. Stimulation of cyanophage induction in response to nutrient addition (phosphate) occurred in only one Tampa Bay sample. Nutrient additions caused a decrease in lytic (or control) phage production in three of three offshore stations, in one of three estuarine experiments, and in a lysogenic marine Synechococcus in culture. These results suggest that the process of cyanophage induction as an assay of Synechococcus lysogeny was not inorganically nutrient limited, at least in the samples examined. More importantly, it was observed that the level of cyanophage induction (cyanophage milliliter(-1)) was inversely correlated to Synechococcus and cyanophage abundance. Thus, the intensity of the prophage induction response is defined by ambient population size and cyanophage abundance. This corroborates prior observations that lysogeny in Synechococcus is favored during times of low host abundance.     

Effect of Nutrient Addition and Environmental Factors on Prophage Induction in Natural Populations of Marine Synechococcus Species

A series of experiments were conducted with samples collected in both Tampa Bay and the Gulf of Mexico to assess the impact of nutrient addition on cyanophage induction in natural populations of Synechococcus sp. The samples were virus reduced to decrease the background level of cyanophage and then either left untreated or amended with nitrate, ammonium, urea, or phosphate. Replicate samples were treated with mitomycin C to stimulate cyanophage induction. In five of the nine total experiments performed, cyanophage induction was present in the non-nutrient-amended control samples. Stimulation of cyanophage induction in response to nutrient addition (phosphate) occurred in only one Tampa Bay sample. Nutrient additions caused a decrease in lytic (or control) phage production in three of three offshore stations, in one of three estuarine experiments, and in a lysogenic marine Synechococcus in culture. These results suggest that the process of cyanophage induction as an assay of Synechococcus lysogeny was not inorganically nutrient limited, at least in the samples examined. More importantly, it was observed that the level of cyanophage induction (cyanophage milliliter⁻¹) was inversely correlated to Synechococcus and cyanophage abundance. Thus, the intensity of the prophage induction response is defined by ambient population size and cyanophage abundance. This corroborates prior observations that lysogeny in Synechococcus is favored during times of low host abundance.     

Identification of cyanophage Ma-LBP and infection of the cyanobacterium Microcystis aeruginosa from an Australian subtropical lake by the virus

Viruses can control the structure of bacterial communities in aquatic environments. The aim of this project was to determine if cyanophages (viruses specific to cyanobacteria) could exert a controlling influence on the abundance of the potentially toxic cyanobacterium Microcystis aeruginosa (host). M. aeruginosa was isolated, cultured, and characterized from a subtropical monomictic lake-Lake Baroon, Sunshine Coast, Queensland, Australia. The viral communities in the lake were separated from cyanobacterial grazers by filtration and chloroform washing. The natural lake viral cocktail was incubated with the M. aeruginosa host growing under optimal light and nutrient conditions. The specific growth rate of the host was 0.023 h(-1); generation time, 30.2 h. Within 6 days, the host abundance decreased by 95%. The density of the cyanophage was positively correlated with the rate of M. aeruginosa cell lysis (r(2) = 0.95). The cyanophage replication time was 11.2 h, with an average burst size of 28 viral particles per host cell. However, in 3 weeks, the cultured host community recovered, possibly because the host developed resistance (immunity) to the cyanophage. The multiplicity of infection was determined to be 2,890 virus-like particles/cultured host cell, using an undiluted lake viral population. Transmission electron microscopy showed that two types of virus were likely controlling the host cyanobacterial abundance. Both viruses displayed T7-like morphology and belonged to the Podoviridiae group (short tails) of viruses that we called cyanophage Ma-LBP. In Lake Baroon, the number of the cyanophage Ma-LBP was 5.6 x 10(4) cyanophage x ml(-1), representing 0.23% of the natural viral population of 2.46 x 10(7) x ml(-1). Our results showed that this cyanophage could be a major natural control mechanism of M. aeruginosa abundance in aquatic ecosystems like Lake Baroon. Future studies of potentially toxic cyanobacterial blooms need to consider factors that influence cyanophage attachment, infectivity, and lysis of their host alongside the physical and chemical parameters that drive cyanobacterial growth and production.     

Genetic diversity and temporal variation in the cyanophage community infecting marine Synechococcus species in Rhode Island's coastal waters

The cyanophage community in Rhode Island's coastal waters is genetically diverse and dynamic. Cyanophage abundance ranged from over 10(4) phage ml(-1) in the summer months to less then 10(2) phage ml(-1) during the winter months. Thirty-six distinct cyanomyovirus g20 genotypes were identified over a 3-year sampling period; however, only one to nine g20 genotypes were detected at any one sampling date. Phylogenetic analyses of g20 sequences revealed that the Rhode Island cyanomyoviral isolates fall into three main clades and are closely related to other known viral isolates of Synechococcus spp. Extinction dilution enrichment followed by host range tests and PCR restriction fragment length polymorphism analysis was used to detect changes in the relative abundance of cyanophage types in June, July, and August 2002. Temporal changes in both the overall composition of the cyanophage community and the relative abundance of specific cyanophage g20 genotypes were observed. In some seawater samples, the g20 gene from over 50% of isolated cyanophages could not be amplified by using the PCR primer pairs specific for cyanomyoviruses, which suggested that cyanophages in other viral families (e.g., Podoviridae or Siphoviridae) may be important components of the Rhode Island cyanophage community.     

Genetic diversity of marine Synechococcus and co-occurring cyanophage communities: evidence for viral control of phytoplankton

Unicellular cyanobacteria of the genus Synechococcus are a major component of the picophytoplankton and make a substantial contribution to primary productivity in the oceans. Here we provide evidence that supports the hypothesis that virus infection can play an important role in determining the success of different Synechococcus genotypes and hence of seasonal succession. In a study of the oligotrophic Gulf of Aqaba, Red Sea, we show a succession of Synechococcus genotypes over an annual cycle. There were large changes in the genetic diversity of Synechococcus, as determined by restriction fragment length polymorphism analysis of a 403- bp rpoC1 gene fragment, which was reduced to one dominant genotype in July. The abundance of co-occurring cyanophage capable of infecting marine Synechococcus was determined by plaque assays and their genetic diversity was determined by denaturing gradient gel electrophoresis analysis of a 118-bp g20 gene fragment. The results indicate that both abundance and genetic diversity of cyanophage covaried with that of Synechococcus. Multivariate statistical analyses show a significant relationship between cyanophage assemblage structure and that of Synechococcus. These observations are consistent with cyanophage infection being a major controlling factor in picophytoplankton succession.     

Genetic Diversity and Temporal Variation in the Cyanophage Community Infecting Marine Synechococcus Species in Rhode Island's Coastal Waters

The cyanophage community in Rhode Island's coastal waters is genetically diverse and dynamic. Cyanophage abundance ranged from over 10⁴ phage ml⁻¹ in the summer months to less then 10² phage ml⁻¹ during the winter months. Thirty-six distinct cyanomyovirus g20 genotypes were identified over a 3-year sampling period; however, only one to nine g20 genotypes were detected at any one sampling date. Phylogenetic analyses of g20 sequences revealed that the Rhode Island cyanomyoviral isolates fall into three main clades and are closely related to other known viral isolates of Synechococcus spp. Extinction dilution enrichment followed by host range tests and PCR restriction fragment length polymorphism analysis was used to detect changes in the relative abundance of cyanophage types in June, July, and August 2002. Temporal changes in both the overall composition of the cyanophage community and the relative abundance of specific cyanophage g20 genotypes were observed. In some seawater samples, the g20 gene from over 50% of isolated cyanophages could not be amplified by using the PCR primer pairs specific for cyanomyoviruses, which suggested that cyanophages in other viral families (e.g., Podoviridae or Siphoviridae) may be important components of the Rhode Island cyanophage community.     

噬藻体感染相关基因的研究进展

噬藻体是感染蓝细菌(蓝藻)的病毒,能调控蓝细菌种群的丰度和多样性,在许多水生生态系统的食物网动态变化和生物地球化学循环中起关键作用。噬藻体与宿主细胞发生各种相互作用,包括吸附、入侵和复制,参与感染过程,从而完成噬藻体的生命周期。本文在综述噬藻体生命周期与基因组结构相互关联的基础上,重点介绍噬藻体与宿主蓝细菌相互作用的蛋白,如噬藻体吸附蛋白、内肽酶、穿孔素、DNA聚合酶、藻胆体降解蛋白A(NblA)、毒力因子、抗CRISPR蛋白(Acr)和小分子热休克蛋白等,分析它们的分子特性,阐述它们在噬藻体感染蓝细菌以及噬藻体-蓝细菌相互作用的分子机制。为了更好地认识驱动不同噬藻体与宿主及水生环境相互作用的策略、感染效率及生态学影响,本文不仅对这些与噬藻体感染相关的重要基因研究动态进行综述与讨论,还在了解噬藻体丰富的多样性和复杂性的基础上,提出应用新技术对噬藻体感染相关基因的功能进行广泛研究,以期扩展全球水生病毒数据库,进一步认识噬藻体与宿主的相互作用机理。     

Identification of Cyanophage Ma-LBP and Infection of the Cyanobacterium Microcystis aeruginosa from an Australian Subtropical Lake by the Virus

Viruses can control the structure of bacterial communities in aquatic environments. The aim of this project was to determine if cyanophages (viruses specific to cyanobacteria) could exert a controlling influence on the abundance of the potentially toxic cyanobacterium Microcystis aeruginosa (host). M. aeruginosa was isolated, cultured, and characterized from a subtropical monomictic lake—Lake Baroon, Sunshine Coast, Queensland, Australia. The viral communities in the lake were separated from cyanobacterial grazers by filtration and chloroform washing. The natural lake viral cocktail was incubated with the M. aeruginosa host growing under optimal light and nutrient conditions. The specific growth rate of the host was 0.023 h⁻¹; generation time, 30.2 h. Within 6 days, the host abundance decreased by 95%. The density of the cyanophage was positively correlated with the rate of M. aeruginosa cell lysis (r² = 0.95). The cyanophage replication time was 11.2 h, with an average burst size of 28 viral particles per host cell. However, in 3 weeks, the cultured host community recovered, possibly because the host developed resistance (immunity) to the cyanophage. The multiplicity of infection was determined to be 2,890 virus-like particles/cultured host cell, using an undiluted lake viral population. Transmission electron microscopy showed that two types of virus were likely controlling the host cyanobacterial abundance. Both viruses displayed T7-like morphology and belonged to the Podoviridiae group (short tails) of viruses that we called cyanophage Ma-LBP. In Lake Baroon, the number of the cyanophage Ma-LBP was 5.6 × 10⁴ cyanophage·ml⁻¹, representing 0.23% of the natural viral population of 2.46 × 10⁷·ml⁻¹. Our results showed that this cyanophage could be a major natural control mechanism of M. aeruginosa abundance in aquatic ecosystems like Lake Baroon. Future studies of potentially toxic cyanobacterial blooms need to consider factors that influence cyanophage attachment, infectivity, and lysis of their host alongside the physical and chemical parameters that drive cyanobacterial growth and production.     

Distribution, isolation, host specificity, and diversity of cyanophages infecting marine Synechococcus spp. in river estuaries.

The abundance of cyanophages infecting marine Synechococcus spp. increased with increasing salinity in three Georgia coastal rivers. About 80% of the cyanophage isolates were cyanomyoviruses. High cross-infectivity was found among the cyanophages infecting phycoerythrin-containing Synechococcus strains. Cyanophages in the river estuaries were diverse in terms of their morphotypes and genotypes.     

新型淡水微囊藻噬藻体vB＿MweS-yong2的分离与基因组分析

【目的】蓝藻(cyanobacteria)水华频繁暴发,引起水质恶化,使水生生物大量死亡,给水产养殖业造成巨大的经济损失;其代谢产物藻毒素具有肝毒性、神经毒性、生殖毒性、遗传毒性和肿瘤促进作用,并可在水生生物中富集,造成饮用水安全风险和水产品食用安全风险。噬藻体(cyanophages)是一类特异性侵染蓝藻的病毒,参与调控蓝藻的种群密度和丰度,被认为是极具潜力的蓝藻水华生物防控工具。以往的研究报道多集中于海水噬藻体,有关淡水噬藻体的报道寥寥无几,迄今尚无惠氏微囊藻(Microcystis wesenbergii)噬藻体的研究报道。本研究的目的在于分离、鉴定惠氏微囊藻噬藻体。【方法】以惠氏微囊藻FACHB-1112为指示宿主,采用双层平板法从淡水中分离出噬藻体vB＿MweS-yong2,对其进行全基因组测序、基因功能注释和系统进化分析。【结果】vB＿MweS-yong2的基因组长44 530 bp,G+C含量为71.6%,有61个开放阅读框(ORF)、1个tRNA基因。成对序列比较(pairwise sequence comparison,PASC)表明,vB＿MweS-yong2与所有...     

感染丝状蓝藻的噬藻体的裂解周期和释放量的测定

近年来 ,随着浮游病毒的认识的深入 ,人们认识到浮游病毒对水体中初级生产力的影响是巨大的[1] ,其主要证据就是发现噬藻体在海洋蓝藻的种群控制上发挥着重要作用[2 ] 。噬藻体的释放量和裂解周期是衡量噬藻体感染力的重要指标 ,很多重要的生态指标如病毒在生态系统中对宿主的致死率、病毒种群得以维持的阈浓度等都需要使用病毒的释放量和裂解周期来加以推算[3,4 ] ,因此准确地测定这两个基本参数是十分重要的。在自然界 ,很多丝状蓝藻 ,如颤藻、鱼腥藻、螺旋藻、席藻等是能够形成水华的 ,其中有些还具有产毒的功能[5] 。丝状蓝藻的形态特征…     

Phages of the marine cyanobacterial picophytoplankton

Cyanobacteria of the genera Synechococcus and Prochlorococcus dominate the prokaryotic component of the picophytoplankton in the oceans. It is still less than 10 years since the discovery of phages that infect marine Synechococcus and the beginning of the characterisation of these phages and assessment of their ecological impact. Estimations of the contribution of phages to Synechococcus mortality are highly variable, but there is clear evidence that phages exert a significant selection pressure on Synechococcus community structure. In turn, there are strong selection pressures on the phage community, in terms of both abundance and composition. This review focuses on the factors affecting the diversity of cyanophages in the marine environment, cyanophage interactions with their hosts, and the selective pressures in the marine environment that affect cyanophage evolutionary biology.     

Novel virulent and temperate cyanophages predicted to infect Microcoleus associated with anatoxin-producing benthic mats

Cyanophages are crucial for regulating cyanobacterial populations, but their influence on anatoxin-producing Microcoleus mat dynamics remains unexplored. Here, we use metagenomics to explore phage presence in benthic mats from the Wolastoq|Saint John River (New Brunswick, Canada) and the Eel River (California, USA). We recovered multiple viral-like sequences associated with different putative bacterial hosts, including two cyanophage genomes with apparently different replication strategies. A temperate cyanophage was found integrated in the genomes of Microcoleus sp. 3 recovered from the Eel River and is phylogenetically related to Phormidium phages. We also recovered novel virulent cyanophage genomes from Wolastoq and Eel River mats that were dominated by anatoxin-producing Microcoleus species predicted to be the host. Despite the geographical distance, these genomes have similar sizes (circa 239 kbp) and share numerous orthologous genes with high sequence identity. A considerable reduction of the anatoxin-producing Microcoleus species in Wolastoq mats following the emergence of the virulent phage suggests that phage infections have an important role in limiting the abundance of this toxigenic cyanobacterium and releasing anatoxins into the surrounding water. Our results constitute the first report of cyanophages predicted to infect mat-forming Microcoleus species associated with anatoxin production.     

东北稻田水体噬藻体psbA基因多样性

【目的】揭示东北稻田噬藻体psbA基因多样性,分析其系统进化地位,为噬藻体生态学研究提供数据支持。【方法】采用滤膜分离并浓缩噬体、PCR-克隆测序技术对我国东北稻田水体中噬藻体psbA基因进行调查。【结果】在东北稻田水体中共得到17条来自于噬藻体的psbA基因,经系统进化分析表明,我国东北稻田具有新的噬藻体的类群,与日本稻田生态系统中psbA基因类群相比,两地间噬藻体类群存在显著的差异,稻田水体中噬藻体psbA基因类群有别于海洋、湖泊类群。【结论】采用PCR-克隆测序技术以psbA基因为分子标记首次对我国东北稻田水体噬藻体类群进行调查,发现有新的噬藻体类群。     

Distribution, Isolation, Host Specificity, and Diversity of Cyanophages Infecting Marine Synechococcus spp. in River Estuaries

The abundance of cyanophages infecting marine Synechococcus spp. increased with increasing salinity in three Georgia coastal rivers. About 80% of the cyanophage isolates were cyanomyoviruses. High cross-infectivity was found among the cyanophages infecting phycoerythrin-containing Synechococcus strains. Cyanophages in the river estuaries were diverse in terms of their morphotypes and genotypes.     

Occurrence of a Sequence in Marine Cyanophages Similar to That of T4 g20 and Its Application to PCR-Based Detection and Quantification Techniques

Viruses are ubiquitous components of marine ecosystems and are known to infect unicellular phycoerythrin-containing cyanobacteria belonging to the genus Synechococcus. A conserved region from the cyanophage genome was identified in three genetically distinct cyanomyoviruses, and a sequence analysis revealed that this region exhibited significant similarity to a gene encoding a capsid assembly protein (gp20) from the enteric coliphage T4. The results of a comparison of gene 20 sequences from three cyanomyoviruses and T4 allowed us to design two degenerate PCR primers, CPS1 and CPS2, which specifically amplified a 165-bp region from the majority of cyanomyoviruses tested. A competitive PCR (cPCR) analysis revealed that cyanomyovirus strains could be accurately enumerated, and it was demonstrated that quantification was log-linear over ca. 3 orders of magnitude. Different calibration curves were obtained for each of the three cyanomyovirus strains tested; consequently, cPCR performed with primers CPS1 and CPS2 could lead to substantial inaccuracies in estimates of phage abundance in natural assemblages. Further sequence analysis of cyanomyovirus gene 20 homologs would be necessary in order to design primers which do not exhibit phage-to-phage variability in priming efficiency. It was demonstrated that PCR products of the correct size could be amplified from seawater samples following 100× concentration and even directly without any prior concentration. Hence, the use of degenerate primers in PCR analyses of cyanophage populations should provide valuable data on the diversity of cyanophages in natural assemblages. Further optimization of procedures may ultimately lead to a sensitive assay which can be used to analyze natural cyanophage populations both quantitatively (by cPCR) and qualitatively following phylogenetic analysis of amplified products.     

紫外光和日光对噬藻体PP活性的影响

分别研究了实验室条件卜紫外灯照射及不同季节中目光照射对噬藻体PP活性的影响。结果表明紫外光(UV-A和UV-B)对噬藻体PP有较强的致失活作用,并且其致失活作用强弱与波长有关。日光的作用下,夏季时噬藻体PP的日失活率为88．60％,冬季时为58．86％。同时发现不同季节中,尽管在某些时段的目光强度相似,但噬藻体PP失活率的差别却较大,这一现象可能是由于光质不同引起的。上述结果有助于解释淡水环境中噬藻体种群大小的季节性波动。     

一种浓缩噬藻体的反冲超滤技术

噬藻体(Cyanophage)是一类感染蓝藻的病毒,形态上同于噬菌体,近期的研究表明,噬藻体作为水体环境中活跃的动态因子,在控制水体初级生产力和有害藻类水华(Harmful Algal Bloom,HAB)方面可能发挥着重要的作用,甚至影响水体生态系统中食物链的结构,因此研究水体中噬藻体的生理生态学特性对于了解其生态功能是非常重要的,但是由于自然水体中的噬藻体浓度往往较低,难以直接对其进行定性或定量研究,所以对天     

Spatial and temporal changes of cyanophage communities in paddy field soils as revealed by the capsid assembly protein gene g20

Bacteriophages are ubiquitous in various environments. Our previous study revealed the diversity of the cyanophage community in paddy floodwater. In this study, the phylogeny and genetic diversity of cyanophage communities in paddy field soils were reported. The viral capsid assembly protein gene (g20) of cyanophage was amplified with the primers CPS1 and CPS8 from soil DNA extracted during two different sampling times at three sampling sites in Japan. The sequencing results indicated that about 93% of the clones were g20 genes. In total, 70 clones of g20 genes were obtained in this study, of which 69 clones were of cyanophage origin. As evaluated by g20 sequence assemblages in paddy field soils, the unifrac analyses results indicated that cyanophage communities changed among the sampling sites and times and differed from those communities detected in paddy floodwater. The phylogenetic analysis showed that the g20 sequences in paddy field soils were very diverse and distributed into Clusters α, β and ?, as well as four newly formed clusters. Within Clusters β and ?, four unique subclusters were formed from the g20 clones that were only observed in this study. These findings suggested that the cyanophage communities in paddy field soils are different from those found in freshwater, marine water and paddy floodwater.