云南不同高原湖泊噬藻体psbA基因多样性

【目的】噬藻体(cyanophage)广泛存在于自然水体生态系统中,通过侵染蓝藻进而调控蓝藻种群及群落结构,具有重要生态功能和生态地位,在控制蓝藻水华方面有巨大开发潜力。本研究旨在探究云南高原湖泊噬藻体psbA基因多样性,分析其系统进化地位,为深入了解高原湖泊生态功能、开发利用噬藻体资源奠定理论基础。【方法】以云南高原主要湖泊滇池、抚仙湖和星云湖等为研究对象,以psbA基因作为分子靶标,对湖泊水体中噬藻体遗传多样性进行研究。【结果】从不同湖泊中共获得100条环境噬藻体psbA基因序列,系统发育分析表明,湖泊的噬藻体psbA基因序列与中国东湖、中国东北稻田、日本稻田等淡水中的环境噬藻体psbA基因亲缘关系较近,与海洋环境噬藻体psbA基因亲缘关系较远;抚仙湖中的噬藻体psbA基因多样性高于滇池、星云湖和异龙湖中的噬藻体psbA基因多样性;云南高原湖泊中存在新的噬藻体类群;各湖泊秋冬季节噬藻体psbA基因遗传多样性差异不明显。【结论】云南主要高原湖泊噬藻体psbA基因遗传多样性高,与淡水环境噬藻体psbA基因亲缘关系较近,且存在独特的噬藻体类群。     

纳帕海高原湿地噬藻体g20基因系统发育多样性分析

【背景】噬藻体是感染蓝藻的病毒,是水生系统的重要组成部分。它们对宿主种群死亡率有重要影响,是控制蓝藻水华生消的潜在因子,对蓝藻群落结构的调控具有重要意义。大量研究揭示了海洋和淡水环境中噬藻体的高度多样性,但目前对高原湿地中噬藻体的多样性知之甚少。【目的】阐明我国纳帕海高原湿地噬藻体g20基因的遗传多样性,为进一步开展高原湿地微生物资源及其生态功能研究提供理论基础。【方法】采集雨季的水体样品,以衣壳蛋白基因g20为标记基因,利用特异性引物Cps1和Cps8对其进行PCR扩增,得到26条不同的g20基因有效序列,并将其与其他生境中g20基因序列进行主坐标分析和系统发育分析。【结果】与其他海洋和淡水的噬藻体序列相比,纳帕海高原湿地中噬藻体的序列与其他稻田序列更为相近;但也存在部分序列单独聚簇,这可能为纳帕海高原湿地中独有的噬藻体类型。【结论】表明该地区的噬藻体较丰富,并具有一定的独特性。     

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。     

大庆湿地可培养噬藻体的分离及其相关基因的系统进化分析

【目的】揭示大庆湿地可培养蓝藻噬菌体遗传基因多样性,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】以鱼腥藻(Anabaena PCC7120)为宿主,采用液体富集和双层平板法分离大庆湿地水体中可培养的噬藻体,提取噬藻体混合液的DNA,PCR扩增噬藻体编码衣壳组装蛋白的g20基因和编码T7型短尾病毒的核糖体聚合酶的pol基因,克隆测序,构建系统进化树,明确可培养噬藻体相关基因的系统进化地位。【结果】克隆测序获得1条g20基因序列,4条pol基因序列。系统进化分析表明,获得g20序列隶属于可培养噬藻体类群(Clusterδ)中。而3条pol基因与我国吉林碱性稻田水体噬藻体类群(PG-Pol-I和PG-Pol-II)更相近,另一条pol序列形成独立的进化分枝。【结论】这是首次调查大庆湿地水体侵染鱼腥藻的可培养噬藻体的g20和pol基因,初步确认以鱼腥藻(Anabaena PCC7120)为宿主的可培养噬藻体g20基因归属于Clusterδ中,而大庆湿地可培养噬藻体的pol基因与我国大安稻田水体pol基因相近。     

纳帕海高原湿地T4类噬菌体遗传多样性分析

噬菌体在微生物中分布较广。为研究T4类噬菌体在纳帕海高原湿地的分布情况,本研究从纳帕海湿地分别采集水样和淤泥土样,采用g23基因为分子探针,利用MZIA1和MZIA6引物对其进行扩增,共获得92条基因序列,并与其他不同生境的g23基因进行比对和遗传多样性研究。结果显示,纳帕海高原湿地的T4类噬菌体与海洋基因序列相距较远,而与淡水湖泊和稻田土壤及平原基因序列相距较近。但也有部分序列独立聚簇,推测其为纳帕海地区的独有基因序列。本研究充分说明纳帕海地区拥有独特而丰富的微生物资源,为研究高原淡水湖泊中噬菌体的生态功能提供了理论依据。     

纳帕海高原湿地mazG遗传多样性初步研究

mazG基因广泛存在于细菌和病毒中,其功能大多数未知,仅在大肠杆菌中的功能被证实。为揭示纳帕海高原湿地mazG遗传多样性,本研究于纳帕海高原湿地采集旱季泥炭土样品,提取总的基因组,以特异性引物对其mazG基因进行扩增,得到不同的mazG有效序列共39条,并与其它细菌及病毒进行系统发育分析和PCoA分析。通过研究得知,纳帕海高原湿地的部分mazG基因和其它细菌及病毒的mazG序列相接近,其余mazG序列的遗传距离较远,推测其可能为纳帕海高原湿地独有的类群。     

流式细胞仪检测纳帕海高原湿地浮游病毒和浮游细菌丰度

【背景】浮游病毒是水体微生物群落中重要的组成成分,深入研究浮游病毒的时空分布有助于更好地保护和开发当地的微生物资源。【目的】对采集到的纳帕海高原湿地水样中的浮游病毒和浮游细菌进行计数,揭示纳帕海高原湿地浮游病毒的分布规律。【方法】采用流式细胞仪检测2013年12月和2014年9月纳帕海高原湿地7个水样的浮游病毒与浮游细菌丰度,并对影响浮游病毒丰度的因素,如细菌丰度、叶绿素a含量以及其他环境因子进行了相关性分析。【结果】季节分布上,雨季浮游病毒和浮游细菌丰度高于旱季;水平分布上,原水样品的浮游病毒高于湿地水和淤泥水。旱季水样的浮游病毒丰度受到细菌丰度及叶绿素a浓度的影响较大;雨季水样的浮游病毒丰度受到水体的p H值和温度的影响较大。【结论】纳帕海高原湿地的浮游病毒和浮游细菌是比较活跃的。浮游病毒丰度在不同季节、不同采样点受到细菌丰度和叶绿素a浓度等因素的不同影响。在旱季噬菌体而非噬藻体或浮游植物病毒是纳帕海高原湿地中浮游病毒的优势种群。     

纳帕海高原湿地真菌群落多样性和组成的分布

【背景】位于滇西北的纳帕海高原湿地,是我国唯一的低纬度、高海拔、季节性半封闭型高原湿地。真菌在湿地生态系统的维持和稳定中发挥着特殊作用,然而关于纳帕海高原湿地真菌群落多样性和组成的研究目前仍无报道。【目的】对纳帕海高原湿地不同季节和土壤类型真菌群落多样性和组成及与环境因子的关系开展系统研究分析,促进对高原湿地微生物多样性的深入认识。【方法】采用荧光定量PCR和高通量测序技术,分析了纳帕海高原湿地不同季节和土壤类型中真菌的数量、群落多样性和组成及其与环境因子的关系。【结果】真菌数量级的变化对于人为干扰下的湿地土壤退化是敏感的响应指标。在真菌群落组成中,约有60%以上未确定的分类信息,40%有确定分类信息的包括6个门17个纲37个目53个科63个属,大部分分类信息集中在Ascomycota门,相对优势属为Gibberella。通过分类水平、OTU水平和β多样性分析比较,在纳帕海高原湿地整体真菌群落多样性和组成受季节变化影响不显著,但不同土壤类型的变化呈显著差异,推测是由于不同采样区植物根际效应和种类的影响。CCA (Canonical correlation analysis)分析表明,在不同采样区受不同土壤理化因子的影响。【结论】揭示了纳帕海高原湿地土壤真菌群落多样性和组成的区域特征,从微生物学角度进一步提出了对纳帕海高原湿地环境保护和恢复的重要性。     

不同自然环境下噬藻体g20基因多样性研究进展北大核心CSCD

随着分子生物学技术发展与病毒基因组测序的推进,对地球上数量最大且广泛存在的病毒及其基因多样性的研究备受科学家们关注。迄今为止,仍未发现类似于细菌16S rDNA和真菌18S rDNA的病毒通用分子标记,但利用病毒某些家族的保守氨基酸序列设计简并性引物可研究环境中病毒多样性,并取得了一系列突破性成果。本文以编码噬藻体壳组装蛋白基因g20为目标,综述了噬藻体在海洋、湖泊和稻田中噬藻体基因多样性的研究进展,讨论了噬藻体g20基因分布与生存环境的相关性,发现不同的自然环境中都存在着独特的类群。同时指出了针对环境中噬藻体g20基因研究存在的问题及未来研究发展的趋势。     

噬藻体光合作用基因研究

感染原绿球藻和聚球藻的噬藻体基因组中普遍存在与psbA、psbD和hli等同源的基因,这些基因编码的蛋白参与光合作用,是光合成反应中心II(photosystem II,PSII)的重要组成成分,在噬藻体感染蓝藻过程中可能发挥着重要的作用。一些假说认为这些基因可能来自于宿主并发生共进化。因此,光合作用基因的功能、起源与演变及基因多样性分布引起了人们的关注。     

Novel cyanophage photosynthetic gene psbA in the floodwater of a Japanese rice field

The gene psbA , encoding the D1 protein involved in photosynthesis, was recently found in a number of cultured cyanophages infecting marine Synechococcus and Prochlorococcus and in environmental samples from marine and freshwaters. In this study, viral concentrates were prepared by sampling the floodwaters from each of four plots in a Japanese rice field: (1) no fertilizer; (2) P and K chemical fertilizers; (3) N, P and K chemical fertilizers; and (4) chemical fertilizers with compost. Fragments of the cyanophage psbA gene were amplified by PCR from DNA in the viral concentrates, with primers psbA -F and psbA -R. Double denaturing gradient gel electrophoresis was conducted to obtain different psbA clones. Phylogenetic analyses indicated that the majority of the psbA sequences in the floodwater formed two unique groups, with their sequences being more closely related to those from freshwater samples than the sequences obtained from marine waters, suggesting that psbA genes in terrestrial aquatic environments are different from those in marine environments.     

Prevalence of highly host-specific cyanophages in the estuarine environment

Cyanophages that infect coastal and oceanic Synechococcus have been studied extensively. However, no cyanophages infecting estuarine Synechococcus have been reported. In this study, seven cyanophages (three podoviruses, three siphoviruses and one myovirus) isolated from four estuarine Synechococcus strains were characterized in terms of their morphology, host range, growth and genetic features. All the podoviruses and siphoviruses were highly host specific. For the first time, the photosynthesis gene ( psbA ) was found in two podoviruses infecting estuarine Synechococcus . However, the psbA gene was not detected in the three siphoviruses. The psbA sequences from the two Synechococcus podoviruses clustered with some environmental psbA sequences, forming a unique cluster distantly related to previous known psbA clusters. Our results suggest that the psbA among Synechococcus podoviruses may evolve independently from the psbA of Synechococcus myoviruses. All three estuarine Synechococcus podoviruses contained the DNA polymerase ( pol ) gene, and clustered with other podoviruses that infect oceanic Synechococcus and Prochlorococcus , suggesting that the DNA pol is conserved among marine picocyanobacterial podoviruses. Prevalence of host-specific cyanophages in the estuary suggests that Synechococcus and their phages in the estuarine ecosystem may develop a host–phage relationship different from what have been found in the open ocean.     

A phylogenetic approach to detect selection on the target site of the antifouling compound irgarol in tolerant periphyton communities

Using DNA sequence data for phylogenetic assessment of toxicant targets is a new and promising approach to study toxicant-induced selection in communities. Irgarol 1051 is a photosystem (PS) II inhibitor used in antifouling paint. It inhibits photosynthesis through binding to the D1 protein in PS II, which is encoded by the psbA gene found in genomes of chloroplasts, cyanobacteria and cyanophages. psbA mutations that alter the target protein can confer tolerance to PS II inhibitors. We have previously shown that irgarol induces community tolerance in natural marine periphyton communities and suggested a novel tolerance mechanism, involving the amino acid sequence of a turnover-regulating domain of D1, as contributive to this tolerance. Here we use a large number of psbA sequences of known identity to assess the taxonomic affinities of psbA sequences from these differentially tolerant communities, by performing phylogenetic analysis. We show that periphyton communities have high psbA diversity and that this diversity is adversely affected by irgarol. Moreover, we suggest that within tolerant periphyton the novel tolerance mechanism is present among diatoms only, whereas some groups of irgarol-tolerant cyanobacteria seem to have other tolerance mechanisms. However, it proved difficult to identify periphyton psbA haplotypes to the species or genus level, which indicates that the genomic pool of the attached, periphytic life forms is poorly studied and inadequately represented in international sequence databases.     

Prevalence and evolution of core photosystem II genes in marine cyanobacterial viruses and their hosts

Cyanophages (cyanobacterial viruses) are important agents of horizontal gene transfer among marine cyanobacteria, the numerically dominant photosynthetic organisms in the oceans. Some cyanophage genomes carry and express host-like photosynthesis genes, presumably to augment the host photosynthetic machinery during infection. To study the prevalence and evolutionary dynamics of this phenomenon, 33 cultured cyanophages of known family and host range and viral DNA from field samples were screened for the presence of two core photosystem reaction center genes, psbA and psbD. Combining this expanded dataset with published data for nine other cyanophages, we found that 88% of the phage genomes contain psbA, and 50% contain both psbA and psbD. The psbA gene was found in all myoviruses and Prochlorococcus podoviruses, but could not be amplified from Prochlorococcus siphoviruses or Synechococcus podoviruses. Nearly all of the phages that encoded both psbA and psbD had broad host ranges. We speculate that the presence or absence of psbA in a phage genome may be determined by the length of the latent period of infection. Whether it also carries psbD may reflect constraints on coupling of viral- and host-encoded PsbA–PsbD in the photosynthetic reaction center across divergent hosts. Phylogenetic clustering patterns of these genes from cultured phages suggest that whole genes have been transferred from host to phage in a discrete number of events over the course of evolution (four for psbA, and two for psbD), followed by horizontal and vertical transfer between cyanophages. Clustering patterns of psbA and psbD from Synechococcus cells were inconsistent with other molecular phylogenetic markers, suggesting genetic exchanges involving Synechococcus lineages. Signatures of intragenic recombination, detected within the cyanophage gene pool as well as between hosts and phages in both directions, support this hypothesis. The analysis of cyanophage psbA and psbD genes from field populations revealed significant sequence diversity, much of which is represented in our cultured isolates. Collectively, these findings show that photosynthesis genes are common in cyanophages and that significant genetic exchanges occur from host to phage, phage to host, and within the phage gene pool. This generates genetic diversity among the phage, which serves as a reservoir for their hosts, and in turn influences photosystem evolution.     

滇西北高原典型退化湿地纳帕海植物群落景观多样性

采用时空替代法,运用3S技术,结合植物群落实地调查,研究了云南西北高原典型退化湿地纳帕海的植物群落景观多样性格局。结果表明:人为干扰加速了纳帕海原生沼泽、沼泽化草甸植物群落景观向草甸、垦后湿地植物群落景观演替,湿地环境不断丧失,湿地功能逐渐退化;不同演替阶段沼泽植物群落景观多样性在空间上呈现出不同的格局是对湿地环境变化的响应,体现了湿地环境变化与功能现状,并在一定程度上反映了人为干扰的类型与强度。     

Marine and freshwater cyanophages in a Laurentian Great Lake: evidence from infectivity assays and molecular analyses of g20 genes

While it is well established that viruses play an important role in the structure of marine microbial food webs, few studies have directly addressed their role in large lake systems. As part of an ongoing study of the microbial ecology of Lake Erie, we have examined the distribution and diversity of viruses in this system. One surprising result has been the pervasive distribution of cyanophages that infect the marine cyanobacterial isolate Synechococcus sp. strain WH7803. Viruses that lytically infect this cyanobacterium were identified throughout the western basin of Lake Erie, as well as in locations within the central and eastern basins. Analyses of the gene encoding the g20 viral capsid assembly protein (a conservative phylogenetic marker for the cyanophage) indicate that these viruses, as well as amplicons from natural populations and the ballast of commercial ships, are related to marine cyanophages but in some cases form a unique clade, leaving questions concerning the native hosts of these viruses. The results suggest that cyanophages may be as important in freshwater systems as they are known to be in marine systems.