塔玛亚历山大藻藻际细菌溶藻过程

海洋微藻在生长过程中向周围环境分泌多种胞外产物,形成细菌自由生长的藻际环境,藻际细菌对微藻的生长有一定的调控作用。在指数生长期的塔玛亚历山大藻培养液中加入φ为1%的2216E培养基,在加入2216E后16h内藻细胞全部裂解。用数码显微镜记录了藻细胞形态变化,分别用DAPI法和荧光模拟底物法测定了细菌数量、胞外酶活性变化,结果表明:在溶藻过程中细菌数量、胞外酶活性在第6小时到第10小时增加了50～100倍。塔玛亚历山大藻藻际细菌主要分布在藻细胞表面,其群落结构改变和数量剧增是溶藻的主要原因,细菌分泌的β-葡萄糖苷酶和几丁质酶可能在溶藻过程中起重要作用。     

杉木粉对塔玛亚历山大藻生长的抑制作用

近年来 ,世界范围内赤潮 (HABs)发生的频次有明显增长的趋势。尽管已发展了多种控制赤潮的方法 ,但真正能推广应用的方法寥寥无几 ,寻找新的、高效、经济、无污染的赤潮防治方法仍然是赤潮领域研究的热点。本文研究了杉木粉对赤潮藻———塔玛亚历山大藻 (Alexandriumtamarense)生长的影响 ,并对其机制进行了初步探讨。结果显示 ,杉木粉能明显抑制塔玛亚历山大藻的生长 ,杉木粉对藻细胞有明显的沉降作用 ,其多酚提取物具有显著的抑藻作用。这些结果提示 ,杉木粉可能是一种潜在的控制赤潮藻生长的新材料 ,其抑藻机制可能与杉木粉中的多酚类活性物质和杉木粉对藻的沉降作用有关。     

长江口塔玛亚历山大藻孢囊的形成、发展及其与赤潮动力学的关系

有毒甲藻棗塔玛亚历山大藻(Alexandrium tamarense(Leboru)Balech)在低氮的F\2培养液中会形成休眠孢囊.在试验的递度中,f\20NO3-诱导效率最高,一次性培养中孢囊形成率达到2%.大约73.2%和17.6%的孢囊在接种后的第八天和第九天形成.新形成的孢囊3d后红色体开始出现,并持续地分泌粘性物质,这可能有助于孢囊的扩散和生存.孢囊在15和20℃保存下的休眠期分别为15和10d.孢囊需要温度的改变就能萌发,在20℃条件下孢囊密度分别降到了4.5和0.9个\g,说明2002年亚历山大大藻孢囊在春季和各有一次萌发.赤潮发生过程中产生的孢囊会很快通过萌发回到水体中,无论季节和水温如何.2003年5月DG-26站位表层沉积物中亚历山大藻孢囊密度只有3.3个\g,但这些孢囊均是新形成的.在长江口,种群初始的大小不是决定塔玛亚历山大藻赤潮发生的关键因素.     

塔玛亚历山大藻的生长研究

在室内条件下研究了温度、N和P、维生素、抗生素对有毒赤潮甲藻塔玛亚历山大藻(香港株Ⅱ)生长的影响。结果表明,塔玛亚历山大藻的最适生长温度为21—25℃,最适N、P浓度分别为882—1765μmol/L和18—72μmol/L。复合维生素B1、B6、B12的加入有利于塔玛亚历山大藻的生长,而50U/mL以上的抗生素(氨苄青霉素液体)则对其有明显的抑制作用。     

塔玛亚历山大藻遗传多样性的微卫星分析

应用12个微卫星标记对9株来自欧洲和中国等不同海域的塔玛亚历山大藻(Alexandrium tamarense)进行了遗传多样性分析,探讨了不同地理藻株之间的遗传分化程度和基因流水平,分析了我国沿海塔玛亚历山大藻的遗传多样性。结果表明：9株塔玛亚历山大藻共检测出26个等位基因,其中9个位点具有多态性,多态比率75%。有效等位基因数1.3243～3.2667,平均为1.8774。塔玛亚历山大藻种内基因多样性为0.3630。9株塔玛亚历山大藻大致可以分为3个进化支,进化支与藻株的地理位置相关联。其中,中国海域的塔玛亚历山大藻至少可分为2个进化支。不同地理分布的塔玛亚历山大藻的遗传分化水平较高,达0.7522。种群间的基因流估算水平较低,提示3个种群间可能不存在基因交流。     

浙江南麂海域塔玛亚历山大藻种群动态及其与环境因子的关系

基于2006年4月至2007年3月在浙江南麂海域的调查结果,对南麂海域塔玛亚历山大藻的种群动态及其与环境因子的关系进行了研究.结果表明：塔玛亚历山大藻在南麂海域仅出现在春季（4—6月）;藻细胞密度在春季呈规则的单峰曲线,表层水体中藻细胞密度的最高值（12250 cells·L^-1）出现在5月8日;塔玛亚历山大藻集中出现在水温18.5 ℃～19.5℃、盐度29.5‰～31.0‰的水体中;较高的藻细胞密度与较低的磷酸盐浓度相对应,氮盐浓度的变化与藻细胞密度之间没有明显的对应关系.逐步线性回归结果表明,塔玛亚历山大藻细胞密度与N∶P存在显著的正相关关系.     

N、P营养盐对塔玛亚历山大藻(Alexandrium tamarense)生长的影响

模拟自然海水营养盐浓度状况,在N、P浓度分别为10-500μg L-1 N和0.74-74μg L-1 P时,研究N、P双因子限制(N、P浓度同时降低,N:P固定为15:1)及单因子限制(保持N或P为最高浓度,只降低一种营养盐浓度)对有毒赤潮藻塔玛亚历山大藻(Alexandrium tamarense)生长的影响。结果表明,塔玛亚历山大藻细胞能较快进入对数生长期,但N、P双因子限制能明显影响其生长,在N、P浓度分别低于100μg L-1 N和15μg L-1 P时,细胞密度无明显增长;而N或P分别受限时,生长态势明显优于N、P同时受到限制的试验组,而且N、P单因子中度限制对生长影响较小。结果说明塔玛亚历山大藻对单因子营养元素限制较强的适应能力,可使其在常常出现单营养因子限制的自然水体中维持一定生长速率和细胞密度,并有助于滤食该藻的贝类体内麻痹性贝类毒素的积累。     

塔玛亚历山大藻双向电泳蛋白的三种提取方法比较

【目的】比较3种蛋白质提取方法,找到适用于塔玛亚历山大藻蛋白的最佳的提取方法,为后续用双向电泳(2-DE)技术研究不同条件下塔玛亚历山大藻蛋白的差异表达奠定基础。【方法】以塔玛亚历山大藻为研究对象,运用Tris-HCl提取法、TCA沉淀法和lysis buffer提取法分别提取塔玛亚历山大藻蛋白,并通过双向电泳技术,对这3种方法进行了比较分析,筛选出最适于塔玛亚历山大藻的蛋白提取方法。并运用以上得出的方法,以不加杀藻物质的无菌塔玛亚历山大藻为对照,比较分析了塔玛亚历山大藻在加入杀藻物质后的蛋白差异表达状况。【结果】在这3种方法中,lysis buffer提取法得到的蛋白溶解性好,进行双向电泳时,可得到干净的背景、清晰的蛋白点,并且蛋白点的数目较多,酸性蛋白、碱性蛋白、大分子量和小分子量的蛋白均有提出来,蛋白点在胶面上分布均匀。用这种方法初步分析了加入杀藻物质后塔玛亚历山大藻蛋白的差异表达情况,并鉴定出14个与塔玛亚历山大藻生理活动密切相关的蛋白质。【结论】lysis buffer提取法获得了最多的蛋白点,双向电泳图谱清晰,适于用来提取塔玛亚历山大藻蛋白。     

塔玛亚历山大藻对黑褐新糠虾存活、生长以及种群繁殖的影响

通过塔玛亚历山大藻 ( Alexandrium tamarense)对黑褐新糠虾 ( N eomysis awatschensis)的急性和慢性毒性作用研究 ,发现塔玛亚历山大藻对黑褐新糠虾的存活、生殖、生长等有不利影响 ,影响程度随塔玛亚历山大藻藻细胞密度的增加而增加。在 96 h急性毒性实验中 ,塔玛亚历山大藻对黑褐新糠虾的半致死密度为 70 0 0 cells/ml,去藻过滤液中糠虾的死亡率为 2 5 %。在 6 2 d的慢性毒性实验中 ,密度为 90 0 cells/ml的塔玛亚历山大藻对黑褐新糠虾的繁殖有严重影响 ,在此影响下的实验组亲虾产幼虾总数只有 2 7尾 ,仅为对照组产幼虾数目的 1 6 .4 % ;其总产幼虾天数、日最高产幼数分别只有对照的 32 %、4 1 % ,其初次产虾日期也推迟了 3d,并出现了 3次生殖中断。塔玛亚历山大藻对黑褐新糠虾亲虾的存活、生长也有一定的影响 ,处在密度为 90 0 cells/ml塔玛亚历山大藻中的黑褐新糠虾亲虾的存活率只有对照的 6 3% ,糠虾亲虾的体长和体重分别为对照组亲虾的 95 .6 %和 81 .9% ,但差异尚不显著 ( P>0 .0 5 )     

有毒赤潮甲藻塔玛亚历山大藻(香港株Ⅱ)的生长特性研究

在室内条件下研究温度、N和P、维生素、抗生素对有毒赤潮甲藻塔玛亚历山大藻(香港株Ⅱ生长的影响。结果表明,塔玛亚历山大藻的适宜生长温度和N、P浓度分别为21-25℃,882-1765μmol／L和18-72μmol／L。复合维生素B的加入有利于塔玛亚历山大藻的生长,而50Uml^-1以上的抗生素则对其有明显的抑制作用。     

The application of a molecular clock based on molecular sequences and the fossil record to explain biogeographic distributions within the Alexandrium tamarense "species complex" (Dinophyceae)

The cosmopolitan dinoflagellate genus Alexandrium, and especially the A. tamarense species complex, contain both toxic and nontoxic strains. An understanding of their evolution and paleogeography is a necessary precursor to unraveling the development and spread of toxic forms. The inclusion of more strains into the existing phylogenetic trees of the Alexandrium tamarense species complex from large subunit rDNA sequences has confirmed that geographic distribution is consistent with the molecular clades but not with the three morphologically defined species that constitute the complex. In addition, a new clade has been discovered, representing Mediterranean nontoxic strains. The dinoflagellates fossil record was used to calibrate a molecular clock: key dates used in this calibration are the origins of the Peridiniales (estimated at 190 MYA), Gonyaulacaceae (180 MYA), and Ceratiaceae (145 MYA). Based on the data set analyzed, the origin of the genus Alexandrium was estimated to be around late Cretaceous (77 MYA), with its earliest possible origination in the mid Cretaceous (119 MYA). The A. tamarense species complex potentially diverged around the early Neogene (23 MYA), with a possible first appearance in the late Paleogene (45 MYA). A paleobiogeographic scenario for Alexandrium is based on (1) the calculated possible ages of origination for the genus and its constituent groups; (2) paleogeographic events determined by plate movements, changing ocean configurations and currents, as well as climatic fluctuations; and (3) the present geographic distribution of the various clades of the Alexandrium tamarense species complex.     

Species boundaries and global biogeography of the Alexandrium tamarense complex (Dinophyceae)1

Alexandrium catenella (Whedon et Kof.) Balech, A. tamarense (M. Lebour) Balech, and A. fundyense Balech comprise the A. tamarense complex, dinoflagellates responsible for paralytic shellfish poisoning worldwide. The relationships among these morphologically defined species are poorly understood, as are the reasons for increases in range and bloom occurrence observed over several decades. This study combines existing data with new ribosomal DNA sequences from strains originating from the six temperate continents to reconstruct the biogeography of the complex and explore the origins of new populations. The morphospecies are examined under the criteria of phylogenetic, biological, and morphological species concepts and do not to satisfy the requirements of any definition. It is recommended that use of the morphospecies appellations within this complex be discontinued as they imply erroneous relationships among morphological variants. Instead, five groups (probably cryptic species) are identified within the complex that are supported on the basis of large genetic distances, 100% bootstrap values, toxicity, and mating compatibility. Every isolate of three of the groups that has been tested is nontoxic, whereas every isolate of the remaining two groups is toxic. These phylogenetic groups were previously identified within the A. tamarense complex and given geographic designations that reflected the origins of known isolates. For at least two groups, the geographically based names are not indicative of the range occupied by members of each group. Therefore, we recommend a simple group‐numbering scheme for use until the taxonomy of this group is reevaluated and new species are proposed.     

Utility of Amplified Fragment Length Polymorphisms (AFLP) to analyse genetic structures within the Alexandrium tamarense species complex

Phylogenetic analyses of the Alexandrium tamarense species complex using ribosomal RNA sequences show a differentiation of ribotypes/clades into geographic areas and not into the three morphotypes/species A. tamarense, A. fundyense and A. catenella. Different parts of the rRNA operon have proven informative in revealing the existence and the relationships of these geographic clades, whereas even internal transcribed spacer (ITS) regions lack the resolution required to gain a deeper insight into the population structure of the species complex. Here, the utility of the DNA fingerprinting technique Amplified Fragment Length Polymorphism (AFLP) as a possible tool for such purposes was tested. A mixed sampling strategy was used in order to assess the amount of variation of AFLP banding patterns at the level of populations and geographic clades. We also describe optimized methods to achieve a good reproducibility. Our results suggest that AFLPs can provide useful information at the population level using clonal samples from a certain bloom, whereas the amount of variation that we found is too high to allow for meaningful comparisons of a few strains collected from different localities at different time points even though they belong to one geographic clade.     

Positive effects of continuous low nitrate levels on growth and photosynthesis of Alexandrium tamarense (Gonyaulacales, Dinophyceae)

The growth and photosynthesis of Alexandrium tamarense (Lebour) Balech in different nutrient conditions were investigated. Low nitrate level (0.0882 mmol/L) resulted in the highest average growth rate from day 0 to day 10 (4.58 × 10² cells mL^?1 d^?1), but the lowest cell yield (5420 cells mL^?1) in three nitrate level cultures. High nitrate‐grown cells showed lower levels of chlorophyll a‐specific and cell‐specific light‐saturated photosynthetic rate (P_m^{chl a} and P_m^cell), dark respiration rate (R_d^chla and R_d^cell) and chlorophyll a‐specific apparent photosynthetic efficiency (α^chla) than was seen for low nitrate‐grown cells; whereas the cells became light saturated at higher irradiance at low nitrate condition. When cultures at low nitrate were supplemented with nitrate at 0.7938 mmol/L in late exponential growth phase, or with nitrate at 0.7938 mmol/L and phosphate at 0.072 mmol/L in stationary growth phase, the cell yield was drastically enhanced, a 7–9 times increase compared with non‐supplemented control culture, achieving 43 540 cells mL^?1 and 52 300 cells mL^?1, respectively; however, supplementation with nitrate in the stationary growth phase or with nitrate and phosphate in the late exponential growth phase increased the cell yield by no more than 2 times. The results suggested that continuous low level of nitrate with sufficient supply of phosphate may facilitate the growth of A. tamarense.     

Comparison of Suitability of Great Bay, New Jersey, and Parsonage Creek, New York, for Alexandrium tamarense

ABSTRACT. Alexandrium tamarense (Lebour) Balech (= Gonyaulax tamarensis Lebour) has been widely distributed and occasionally abundant in coastal waters of Long Island, New York in recent years. However, the distribution on the New Jersey coast has been sparse and this fact cannot be explained by this dinoflagellate's ability to migrate, or by its nutritional and physiological characteristics, or by the region's general suitability for phytoplankton. Therefore, the possibility that New Jersey coastal waters might be chemically exclusionary for A. tamarense seemed worth exploring. In a limited approach, we tested for water quality detrimental to the species in one New Jersey site (Great Bay) with a series of annual assays. Parsonage Creek, Long Island, New York, was assayed for comparison; this creek is assumed to have had at least marginal suitablity for A. tamarense , based on its reported long-term presence. Results provide tentative support for our working hypothesis, i.e. Great Bay chemical water quality is generally unfavorable for A. tamarense. Inhibition of A. tamarense growth, or culture decline, occurred in both assay series, but was substantially greater in Great Bay water. Inimical water quality was the most important factor distinguishing the two sites. Chelation with EDTA had greatest overall benefit in Great Bay assays, suggesting that lower availability of a natural chelator in the bay could be a secondary factor. Assay metal response is problematic, but we believe it permits speculation that essential metals could be partially limiting to A. tamarense in Great Bay, but would not be a critical regulator.     

Development of microsatellite markers in the toxic dinoflagellate Alexandrium tamarense (Dinophyceae)

Outbreaks of paralytic shellfish poisoning caused by the toxic dinoflagellate Alexandrium tamarense (Dinophyceae) are currently a serious problem from an economic and food hygiene point of view throughout the world. We isolated 13 polymorphic microsatellite loci from this species. These loci provided microsatellite markers with high polymorphism ranging from four to 15 alleles per locus and gene diversity between 0.632 and 0.974. The markers are available for more detailed investigations of genetic structure and gene flow of A. tamarense populations.     

Geographic differences in paralytic shellfish poisoning toxin profiles among Japanese populations of Alexandrium tamarense and A. catenella (Dinophyceae)

To reconsider whether toxin profile could be used as a marker for populations from different geographical areas, clonal isolates of the toxic dinoflagellates Alexandrium tamarense (Lebour) Balech and Alexandrium catenella (Whedon et Kofoid) Balech from Ofunato Bay (Iwate Prefecture), Atsumi Bay (Aichi Prefecture), Tanabe Bay (Wakayama Prefecture), Harima‐Nada (Kagawa Prefecture), Uranouchi Bay (Kochi Prefecture), Hiroshima Bay (Hiroshima Prefecture) and Yamakawa Bay (Kagoshima Prefecture), which were identified on the basis of morphotaxonomy, immunological and molecular biological techniques, were subjected to analysis of paralytic shellfish poisoning toxins by high performance liquid chromatography‐fluorometric method. All the isolates except A. tamarense OF152 from Ofunato Bay contained mainly N‐sulfocarbamoyl toxins (C1 +2) with various amounts of derivatives, and a typical north‐to‐south trend of decreasing toxicity was observed. In both A. tamarense and A. catenella, toxin profiles were rather constant within a geographical area and divergent among different geographical areas. The toxin profiles of A. tamarense from Harima‐Nada were well conserved among different bloom years. Toxin profile showed that isolates of A. tamarense from Ofunato Bay, A. tamarense from Harima‐Nada isolated in 1988 and A. catenella from Uranouchi Bay were heterogeneous. However, only two or three groups of isolates with different toxin profiles were observed in a geographical region, suggesting that several representative isolates express the genotype in a given region. These observations confirmed that toxin composition could be used as a marker to discriminate different geographical populations of these species.     

Vertical distribution and germination ability of Alexandrium spp. cysts (Dinophyceae) in the sediments collected from Kure Bay of the Seto Inland Sea, Japan

The vertical distribution of Alexandrium tamarense/ catenella (hereinafter Alexandrium spp.) cysts was investigated with special attention to living cysts filled with fresh protoplasm and empty cysts. In addition, based on the incubation experiments of Alexandrium spp. cysts, the germination ability of the cysts was examined. A sediment core 63 cm in length, collected from Kure Bay of the Seto Inland Sea, West Japan, in September 2000, was provided for an analysis on the vertical distribution of Alexandrium spp. cysts. Samples from every 1 cm interval depth from the top down to 13 cm depth of the same core were taken to examine the germination ability of the cysts. Results show that Alexandrium spp. cysts were continuously observed from 59 to 60 cm depth to the top. The cyst densities in the upper parts of the core (from 9 to 10 cm depth to the top) were much more abundant those that in the lower parts (below 10–11 cm depth). The relationship between living and empty cysts in each depth did not reveal a positive correlation with the sediment depth. Based on the sedimentation rate of the core sediment (approximately 1.6 cm/year), Alexandrium spp. cysts have been produced since 1962, and a remarkable increase of these cysts was observed from ca 1993. Such a rapid increase of Alexandrium spp. cysts has probably been as a result of dense blooms of A. tamarense occurring since 1992 in Hiroshima Bay, including Kure Bay. The germination of Alexandrium spp. cysts was observed in samples collected from the top to 12–13 cm depth of the core. It suggests that the Alexandrium spp. cysts can keep the germination ability for more than 8 years.     

Loop-mediated isothermal amplification method for rapid detection of the toxic dinoflagellate Alexandrium, which causes algal blooms and poisoning of shellfish

The marine dinoflagellate genus Alexandrium includes a number of species that produce potent neurotoxins responsible for paralytic shellfish poisoning, which in humans may cause muscular paralysis, neurological symptoms and, in extreme cases, death. Because of the genetic diversity of different genera and species, molecular tools may help to detect the presence of target microorganisms in marine field samples. Here we employed a loop-mediated isothermal amplification (LAMP) method for the rapid and simple detection of toxic Alexandrium species. A set of four primers were designed based upon the conserved region of the 5.8S rRNA gene of members of the genus Alexandrium . Using this detection system, toxic Alexandrium genes were amplified and visualized as a ladder-like pattern of bands on agarose gels under isothermal condition within 60 min. The LAMP amplicons were also directly visualized by eye in the reaction tube by the addition of SYBR Green I. This LAMP assay was 10-fold more sensitive than a conventional PCR method with a detection limit of 5 cells per tube when targeting DNA from Alexandrium minutum . The LAMP assay reported here indicates the potential usefulness of the technique as a valuable simple, rapid alternative procedure for the detection of target toxic Alexandrium species during coastal water monitoring.     

Benthic Dinoflagellate Integrator (BEDI): A new method for the quantification of Benthic Harmful Algal Blooms

Despite the potential negative human health, ecological and economic impact, the ecology of harmful benthic dinoflagellate blooms remains largely unknown. This is probably due to the complex interactions among biotic and abiotic drivers that influence blooms, but also to the difficulty in quantifying cell abundance in a comparable way over large spatial and temporal scales. One of the recognized priorities for bHABs (benthic Harmful Algal Blooms) assessment is developing and standardizing methods that can provide comparable data. In this context, the Benthic Dinoflagellates Integrator (BEDI), a new non-destructive quantification method for benthic dinoflagellate abundances, has been developed and tested within the present study. The rationale behind the BEDI standard assessment method is that mechanical resuspension of cells enables the quantification of abundances as cells per unit of seabed surface area (i.e. cells mm⁻²) or as Potentially Resuspended cells per unit of volume (PRcells ml⁻¹), by integrating both cells in the biofilm and those in the surrounding water. Estimations of Ostreopsis performed with BEDI method are independent of the substratum (i.e. macroalgal species) or the dominant ecosystem (i.e. algal forests or turfs, seagrass beds, coral reefs) and potentially allow the comparison of benthic dinoflagellate blooms over broad temporal and spatial scales. The first application of the BEDI method, presented in this study, gave encouraging results: the characterization of blooms of Ostreopsis cf. ovata at three sites in the NW Mediterranean Sea is consistent with results derived from the other commonly applied methods. Quantification of the ratio between abundances of cells in the biofilm and in the surrounding water was calculated for the first time per unit of seabed surface area, demonstrating that the highest abundances of cells (the stock), and therefore the associated risk for human health, are in the biofilm. For risk assessment purposes, conversion values for commonly used monitoring alert thresholds of Mediterranean Ostreopsis blooms are provided.