东海原甲藻（Prorocentrum donghaiense）和链状亚历山大藻（Alexandrium catenella）对模拟食物链物质传递的影响

研究了东海原甲藻的基本营养组成,并就赤潮密度下的东海原甲藻（Prorocentrum donghaiense）和链状亚历山大藻（Alexandrium catenella）在单一和混合情况下对赤潮藻→卤虫模拟食物链物质传递的影响进行了探讨。结果表明：与其它饵料微藻相比,东海原甲藻必需氨基酸中的苯丙氨酸、赖氨酸和组氨酸含量明显偏低。东海原甲藻单独投喂时,卤虫对其的总物质转化效率随着藻密度的增加呈现先逐渐增加再逐渐降低的趋势。而当不同密度的东海原甲藻分别与一种硅藻小新月菱形藻(Nitzschia closterium)混合投喂时,随东海原甲藻密度的增加,卤虫选择性地增加对东海原甲藻的摄食,而降低对小新月菱形藻的摄食,并且其总物质转化效率逐渐降低。暴露于链状亚历山大藻藻液,卤虫体重减轻,且在其体内未检测到叶绿素a,表明卤虫未摄食该藻。当链状亚历山大藻藻细胞重悬液和去藻过滤液分别与小新月菱形藻或东海原甲藻混合时,卤虫对后两株藻的摄食量和总物质转化效率均有所降低。因此,在大规模赤潮发生时,东海原甲藻和链状亚历山大藻可能分别对浮游动物的营养和存活带来不利影响,并影响物质沿食物链的传递。     

东海原甲藻(Prorocentrum donghaiense)和链状亚历山大藻(Alexandrium catenella)对模拟食物链物质传递的影响

研究了东海原甲藻的基本营养组成,并就赤潮密度下的东海原甲藻(Prorocentrum donghaiense)和链状亚历山大藻(Alexandrium catenella)在单一和混合情况下对赤潮藻→卤虫模拟食物链物质传递的影响进行了探讨。结果表明:与其它饵料微藻相比,东海原甲藻必需氨基酸中的苯丙氨酸、赖氨酸和组氨酸含量明显偏低。东海原甲藻单独投喂时,卤虫对其的总物质转化效率随着藻密度的增加呈现先逐渐增加再逐渐降低的趋势。而当不同密度的东海原甲藻分别与一种硅藻小新月菱形藻(Nitzschia closterium)混合投喂时,随东海原甲藻密度的增加,卤虫选择性地增加对东海原甲藻的摄食,而降低对小新月菱形藻的摄食,并且其总物质转化效率逐渐降低。暴露于链状亚历山大藻藻液,卤虫体重减轻,且在其体内未检测到叶绿素a,表明卤虫未摄食该藻。当链状亚历山大藻藻细胞重悬液和去藻过滤液分别与小新月菱形藻或东海原甲藻混合时,卤虫对后两株藻的摄食量和总物质转化效率均有所降低。因此,在大规模赤潮发生时,东海原甲藻和链状亚历山大藻可能分别对浮游动物的营养和存活带来不利影响,并影响物质沿食物链的传递。     

塔玛亚历山大藻和东海原甲藻对褶皱臂尾轮虫种群数量的影响

通过对2002年5月东海赤潮原因种一东海原甲藻和亚历山大藻的单一藻种和两种藻混合情况下对褶皱臂尾轮虫种群数量影响的实验研究,发现塔玛亚历山大藻(ATHK)对轮虫有致死作用,其48hLC50为1300cell·ml^-1．藻的各组分毒性比较研究表明,只有藻液和藻细胞具有这种毒害作用,藻在早期生长阶段的毒害作用较强,毒性大小与藻细胞活性相关．东海原甲藻在高密度(4×10^4、5×10^4、10×10^4cell·ml^-1)时对轮虫种群数量在第5d时开始有影响;东海原甲藻在低密度(1×10^4、2×10^4、3×10^4cell·ml^-1)时,轮虫能够以其为食并进行生长繁殖．两种藻混合情况下,东海原甲藻能够减轻塔玛亚历山大藻对轮虫的毒害作用．实验结果表明,此次赤潮对东海的微型浮游动物种群能够产生一定的影响．     

营养盐限制条件下塔玛亚历山大藻对东海原甲藻的化感作用研究

为明确塔玛亚历山大藻(Alexandrium tamarense)对东海原甲藻(Prorocentrum donghaiense)生长的化感作用,研究了在N、P限制及正常营养盐条件下(又称富营养)塔玛亚历山大藻无细胞滤液对东海原甲藻生长的影响,并探讨了3种不同营养盐条件下两种藻共培养时的生长状况。结果表明,半连续培养时,营养盐限制下,塔玛亚历山大藻无细胞滤液对东海原甲藻的生长均有一定影响。N限制下,5 d后东海原甲藻藻密度显著低于未加滤液的对照组,藻密度为1.02×107 cells L-1,对照组为1.7×107 cells L-1;P限制下,东海原甲藻藻密度与对照组差异不显著,5 d后藻密度为1.44×107 cells L-1;富营养条件下,东海原甲藻藻密度与对照组无明显区别。共培养时,塔玛亚历山大藻对东海原甲藻生长的抑制作用更为显著,N、P限制下,4 d后东海原甲藻全部死亡,且聚集成团形成沉淀;富营养条件下,仍有少量东海原甲藻存活(藻密度3.3×104 cells L-1)。这表明,塔玛亚历山大藻对东海原甲藻的生长有一定的化感作用。营养盐限制可促进塔玛亚历山大藻化感物质的合成和释放,化感作用是塔玛亚历山大藻抑制东海原甲藻生长的原因之一。     

几株赤潮甲藻的摄食能力

采用荧光标记的方法,在营养盐限制条件下,对6株赤潮甲藻对荧光标记的海洋细菌(FLB)、金藻(FLA)和两种粒径分别为0.5μm和2.0μm的荧光微球(FM0.5和FM2.0)4种摄食对象的摄食进行了比较研究。研究结果表明,除了东海原甲藻对4种摄食对象均没有摄食外,其它5株甲藻,微小亚历山大藻、链状亚历山大藻、塔玛亚历山大藻、海洋原甲藻和微小原甲藻均具有摄食能力,但对摄食对象的选择和摄食率有差异,多数摄食率是在4 h达到最大,白天的摄食能力强于夜间。研究说明了在营养盐限制环境中,有些具有兼性营养能力的甲藻对细菌和/或更小浮游植物的摄食能力可能对维持和促进其生长具有不可忽视的作用。     

球形棕囊藻对五种水生动物的急性毒性作用

利用室内半静水法研究球形棕囊藻培养液、藻细胞悬浮液、去藻细胞滤液、藻细胞内容物、藻细胞碎片以及溶血毒素粗提物对卤虫(Artemia sinica)、褶皱臂尾轮虫(Brachionus plicatilis)、蒙古裸腹潘(Moina mongolia)、赤点石斑鱼幼鱼(Epinephelus akaara)和南美白对虾(Penaeus vannamei)5种水生动物的影响,并对其致毒途径进行分析.结果表明,与对照相比,培养液、藻细胞悬浮液处理卤虫,其运动速度下降,培养液、藻细胞悬浮液与毒素粗提物处理轮虫72 h,存活率显著降低(P＜0.05),卤虫、轮虫消化道中充满藻细胞,提示摄食球形棕囊藻可能是引起卤虫、轮虫中毒的主要途径.培养液、滤液和藻细胞内容物对赤点石斑鱼幼鱼均有显著的致死作用,而藻细胞碎片和溶血毒素粗提物对幼鱼的存活无明显影响,表明球形棕囊藻细胞表面并不存在毒性物质,球形棕囊藻可能会分泌有毒物质进入水体,进而影响鱼类的生长.培养液、藻细胞悬浮液、去藻细胞滤液、毒素粗提物处理蒙古裸腹溞72 h虽有死亡,但存活率与对照无显著差异;南美白对虾的情况与蒙古裸腹溞类似,表明球形棕囊藻及相关组分对蒙古裸腹溞和对虾的影响较小.这些结果表明,球形棕囊藻对不同生物的毒害作用不同;摄食和分泌有毒、有害物是球形棕囊藻引致生物中毒的主要途径;除了溶血毒素以外,球形棕囊藻还可能产生其他鱼毒性物质.     

东海原甲藻与中肋骨条藻的种间竞争特征

对东海原甲藻和中肋骨条藻按照起始Chl-a比1∶5、1∶1和5∶1进行了f/2条件下的共培养实验,以探讨这两种藻的种间竞争特征。实验结果表明在共培养体系中,中肋骨条藻完全占优势,而东海原甲藻的生长受到明显的抑制。应用Lotka-Volterra种间竞争模型对共培养实验进行模拟的结果表明,东海原甲藻与中肋骨条藻的种间竞争结果与初始密度配比无关,中肋骨条藻总会竞争胜过东海原甲藻。为了探讨他感作用对东海原甲藻和中肋骨条藻种间竞争的影响,采用了中肋骨条藻的无藻细胞滤液来进行培养实验。实验结果显示,中肋骨条藻滤液对东海原甲藻及其本身的生长均无明显影响,这表明他感作用并非中肋骨条藻获得优势的主要竞争方式。     

不同营养条件对东海原甲藻和中肋骨条藻竞争参数的影响

以东海原甲藻和中肋骨条藻为研究对象,采用室内单种培养和混合培养,设置不同的氮、磷营养条件,研究了不同营养条件对两种微藻的生长状况和种间竞争参数的影响.结果表明:随着氮、磷浓度的增加,两种藻的最大生物量均呈增加趋势,混合培养中两种微藻的比生长率低于单独培养.在混合培养中,生长前期中肋骨条藻是优势种,随着培养时间的延长,东海原甲藻成为优势种,且优势种发生变化的时间与营养条件有关.混合培养中,东海原甲藻拐点出现时间在0.5 ～4.9 d,中肋骨条藻为0～2.6d,东海原甲藻拐点出现时间晚于中肋骨条藻.在各营养条件下,东海原甲藻对中肋骨条藻的竞争抑制参数β均高于中肋骨条藻对东海原甲藻的竞争抑制参数α,当N为128μmol·L-1、P为32 μmol·L-1时,东海原甲藻的竞争能力是中肋骨条藻的3.8倍,两者差异最为明显.     

大型海藻分泌物亚麻酸对东海原甲藻的化感效应

东海原甲藻是常见有毒有害赤潮藻。本文从种群生长、光合效率和抗氧化系统等角度研究大型海藻分泌物亚麻酸胁迫下东海原甲藻的生理生化响应。结果表明:低浓度亚麻酸(200μg·L~(-1))对东海原甲藻的生长具有促进作用,200~1000μg·L~(-1)浓度下,东海原甲藻的生长受到显著抑制,当亚麻酸浓度为1000μg·L~(-1)时,抑藻率达90%;200~1000μg·L~(-1)亚麻酸胁迫下,藻细胞光合色素含量显著降低,最大光能转化效率Fv/Fm降低,当亚麻酸浓度为1000μg·L~(-1)时,F_v/F_m为对照组的33.87%;随着亚麻酸浓度的增大,抗氧化酶活性(过氧化氢酶CAT、超氧化物歧化酶SOD和谷胱甘肽过氧化物酶GPx)与抗氧化非酶物质(还原型谷胱甘肽GSH、氧化型谷胱甘肽GSSG、抗坏血酸As A和脱氢抗坏血酸DHA)含量呈现出先升高后降低趋势;亚麻酸胁迫下丙二醛含量显著升高,表明膜脂过氧化程度加剧。以上结果说明,低浓度亚麻酸对东海原甲藻的生长具有促进作用,高浓度亚麻酸主要通过降低光合效率和细胞过氧化损害抑制东海原甲藻的生长。研究结果为生物法防控以东海原甲藻为优势藻种的赤潮提供了理论基础。     

不同光照条件下米氏凯伦藻和东海原甲藻生长的温度生态幅

米氏凯伦藻和东海原甲藻是我国东南沿海地区赤潮的主要优势种。为定量获取米氏凯伦藻和东海原甲藻生长的温度生态幅,根据3个光照水平(28.32,75.06,111.66μmol m~(-2)s~(-1))条件下4个温度水平(18,22,25,28℃)对米氏凯伦藻和东海原甲藻生长特性的室内培养实验结果,并结合Shelford耐受性定律建立了基于温度的米氏凯伦藻和东海原甲藻比生长率的耐受性模型,最后根据前期的研究成果分别获取了米氏凯伦藻和东海原甲藻生长的最适温度、适温范围及耐受温度范围。结果表明,无论是米氏凯伦藻还是东海原甲藻,在相同培养光照条件下,在设定的温度水平范围内,分别存在一个适宜米氏凯伦藻和东海原甲藻的最适生长温度T_(opt),且当T≤T_(opt)时,米氏凯伦藻和东海原甲藻细胞密度和比生长率随着温度的升高而显著增大;而当T≥T_(opt)时,米氏凯伦藻和东海原甲藻细胞密度和比生长率随着温度的升高而显著减小。随着培养光照强度的升高,米氏凯伦藻和东海原甲藻细胞密度和比生长率均呈现"先升后降"的变化趋势。建立的藻类生长温度耐受性模型与谢尔福德耐受定律较为吻合,定量获取米氏凯伦藻在3个光照水平(28.32,75.06,111.66μmol m~(-2)s~(-1))下的最适生长温度分别为22.48,22.37,22.33℃;适温范围分别为17.93—27.03,17.82—26.92,17.78—26.88℃;耐受温度范围分别为13.38—31.58,13.27—31.47,13.23—31.43℃;东海原甲藻在3个光照水平(28.32,75.06,111.66μmol m~(-2)s~(-1))下的最适生长温度分别为22.10,21.99,21.93℃;适温范围分别为17.59—26.61,17.48—26.5,17.42—26.44℃;耐受温度范围分别为13.08—31.12,12.97—31.01,12.91—30.95℃。     

Effects of toxic Alexandrium species on the survival and feeding rates of brine shrimp, Artemia salina

Zooplankton is an important link between phytoplankton and higher consumers in the marine food chain. To investigate the harmful effects of the toxic dinoflagellate Alexandrium species on zooplankton, 4 strains of Alexandrium spp., isolated from the Chinese coast, were used to test the species' effects on the survival and feeding rates of the brine shrimp, Artemia salina. The experiment was designed to assess the response of A. salina in each stage of its life cycle: nauplii, metanauplii, and adult. Each experiment was conducted in a 500 ml treatment that was added. The toxic treatments consisted of single strains of A. minutum, A. catanella, and A. tamarense (Nanhai and Donghai strain), while non-toxic species (dinoflagellate Prorocentrum donghaiense and diatom Chaetoceros minutissimus) were used as control treatments. An additional phytoplankton treatment consisted of, a mixture of A. tamarense (Nanhai strain) and P. donghaiense. Alexandrium spp. species were found to have lethal effects on the brine shrimp at a density of 2000 cells/ml. All the brine shrimps died within 24-168 hours of inoculation with the 4 treatments each containing single toxic Alexandrium species. During the feeding experiment, toxic Alexandrium spp. caused a reduction in the feeding rates in all the three stages of the life cycle of A. salina, whereas this response was not obvious in the treatment involving the nontoxic species P. donghaiense. The body surface of the brine shrimp that were fed on Alexandrium species was consistently covered by a sticky floc. Mortality of A. salina was observed to increase with the occurrence of the floc. The toxicity of the paralytic shellfish poisons (PSP) produced by the Alexandrium species was not significantly correlated with the survival or the feeding rate of the brine shrimp. When A. tamarense was mixed with P. donghaiense, the lethal effect of A. tamarense decreased, as shown by an increase in the survival and the feeding rates of the brine shrimp. A. salina metanauplii were found at the life stage most sensitive to the toxic algae and hunger. In summary, toxic Alexandrium spp. were found to have lethal effects on A. salina and to restrain the brine shrimp's feeding rate. Nontoxic Prorocentrum mitigated the toxicity of Alexandrium to a certain extent. The results also imply that the sticky material on the surface of the body of the brine shrimp may have been an important lethal factor rather than the PSP toxins.     

Effects of toxic Alexandrium species on the survival and feeding rates of brine shrimp, Artemia salina

Zooplankton is an important link between phytoplankton and higher consumers in the marine food chain. To investigate the harmful effects of the toxic dinoflagellate Alexandrium species on zooplankton, 4 strains of Alexandrium spp., isolated from the Chinese coast, were used to test the species' effects on the survival and feeding rates of the brine shrimp, Artemia salina. The experiment was designed to assess the response of A. salina in each stage of its life cycle: nauplii, metanauplii, and adult. Each experiment was conducted in a 500 ml treatment that was added. The toxic treatments consisted of single strains of A. minutum, A. catanella, and A. tamarense (Nanhai and Donghai strain), while non-toxic species (dinoflagellate Prorocentrum donghaiense and diatom Chaetoceros minutissimus) were used as control treatments. An additional phytoplankton treatment consisted of, a mixture of A. tamarense (Nanhai strain) and P. donghaiense. Alexandrium spp. species were found to have lethal effects on the brine shrimp at a density of 2000 cells/ml. All the brine shrimps died within 24-168 hours of inoculation with the 4 treatments each containing single toxic Alexandrium species. During the feeding experiment, toxic Alexandrium spp. caused a reduction in the feeding rates in all the three stages of the life cycle of A. salina, whereas this response was not obvious in the treatment involving the nontoxic species P. donghaiense. The body surface of the brine shrimp that were fed on Alexandrium species was consistently covered by a sticky floc. Mortality of A. salina was observed to increase with the occurrence of the floc. The toxicity of the paralytic shellfish poisons (PSP) produced by the Alexandrium species was not significantly correlated with the survival or the feeding rate of the brine shrimp. When A. tamarense was mixed with P. donghaiense, the lethal effect of A. tamarense decreased, as shown by an increase in the survival and the feeding rates of the brine shrimp. A. salina metanauplii were found at the life stage most sensitive to the toxic algae and hunger. In summary, toxic Alexandrium spp. were found to have lethal effects on A. salina and to restrain the brine shrimp's feeding rate. Nontoxic Prorocentrum mitigated the toxicity of Alexandrium to a certain extent. The results also imply that the sticky material on the surface of the body of the brine shrimp may have been an important lethal factor rather than the PSP toxins.     

Alexandrium (Dinophyceae) species in Malaysian waters

A study was carried out to determine the presence of paralytic shellfish poisoning (PSP) toxin-producing dinoflagellates in the coastal waters of Peninsula Malaysia. This followed first ever occurrences of PSP in the Straits of Malacca and the northeast coast of the peninsula. The toxic tropical dinoflagellate Pyrodinium bahamense var. compressum was never encountered in any of the plankton samples. On the other hand, five species of Alexandrium were found. They were Alexandrium affine, Alexandrium leei, Alexandrium minutum, Alexandrium tamarense and Alexandrium tamiyavanichii. Not all species were present at all sites. A. tamiyavanichii was present only in the central to southern parts of the Straits of Malacca. A. tamarense was found in the northern part of the straits, while A. minutum was only found in samples from the northeast coast of the peninsula. A. leei and A. affine were found in both the north and south of the straits. Cultured isolates of A. minutum and A. tamiyavanichii were proven toxic by the receptor binding assay for PSP toxins but A. tamarense clones were not toxic. Mean toxin content for the A. tamiyavanichii and A. minutum clones were 26 and 15 fmol per cell STX equivalent, respectively. This study has provided evidence on the presence of PSP toxin-producing Alexandrium species in Malaysian waters which suggests that PSP could increase in importance in the future.     

Experimental study on the impact of dinoflagellate Alexandrium species on populations of the rotifer Brachionus plicatilis

To investigate harmful effects of the dinoflagellate Alexandrium species on microzooplankton, the rotifer Brachionus plicatilis was chosen as an assay species, and tested with 10 strains of Alexandrium including one known non-PSP-producer (Alexandrium tamarense, AT-6). HPLC analysis confirmed the PSP-content of the various strains: Alexandrium lusitanicum, Alexandrium minutum and Alexandrium tamarense (ATHK, AT5-1, AT5-3, ATCI02, ATCI03) used in the experiment were PSP-producers. No PSP toxins were detected in the strains Alexandrium sp1, Alexandrium sp2.Exposing rotifer populations to the densities of 2000 cells ml⁻¹ of each of these 10 Alexandrium strains revealed that the (non-PSP) A. tamarense (AT-6) and two other PSP-producing algae: A. lusitanicum, A. minutum, did not appear to adversely impact rotifer populations. Rotifers exposed to these three strains were able to maintain their population numbers, and in some cases, increase them. Although some increases in rotifer population growth following exposures to these three algal species were noted, the rate was less than for the non-exposed control rotifer groups.In contrast, the remaining seven algal strains (A. tamarense ATHK, AT5-1, AT5-3, ATCI02, ATCI03; also Alexandrium sp1 and Alexandrium sp2) all have adverse effects on the rotifers. Dosing rotifers with respective algal cell densities of 2000 cells ml⁻¹ each, for Alexandrium sp1, Alexandrium sp2, and A. tamarense strains ATHK and ATCI03 showed mean lethal time (LT₅₀) on rotifer populations of 21, 28, 29, and 36h, respectively. The remaining three species (A. tamarense strains AT5-1, AT5-3, ATCI02) caused respective mean rotifer LT₅₀s of 56, 56, and 71 h, compared to 160 h for the unexposed “starved control” rotifers. Experiments to determine ingestion rates for the rotifers, based on changes in their Chlorophyll a content, showed that the rotifers could feed on A. lusitanicum, A. minutum and A. tamarense strain AT-6, but could graze to little or no extent upon algal cells of the other seven strains. The effects on rotifers exposed to different cell densities, fractions, and growth phases of A. tamarense algal culture were respectively compared. It was found that only the whole algal cells had lethal effects, with strongest impact being shown by the early exponential growth phase of A. tamarense. The results indicate that some toxic mechanism(s), other than PSP and present in whole algal cells, might be responsible for the adverse effects on the exposed rotifers.     

The toxigenic marine dinoflagellate Alexandrium tamarense as the probable cause of mortality of caged salmon in Nova Scotia

The toxins associated with paralytic shellfish poisoning (PSP) are potent neurotoxins produced by natural populations of the marine dinoflagellate Alexandrium tamarense. In early June 2000, a massive bloom (>7×10⁵ cells l⁻¹) of this dinoflagellate coincided with an unusually high mortality of farmed salmon in sea cages in southeastern Nova Scotia. Conditions in the water column in the harbour were characterised by the establishment of a sharp pycnocline after salinity stratification due to abundant freshwater runoff. In situ fluorescence revealed a high sub-surface (2–4 m depth) chlorophyll peak related to the plankton bloom. The intense bloom was virtually monospecific and toxicity was clearly related to the concentration of Alexandrium cells in plankton size fractions. Cultured clonal isolates of A. tamarense from the aquaculture sites were very toxic on a per cell basis and yielded a diversity of PSP toxin profiles, some of which were similar to those from plankton concentrates from the natural bloom population. The toxin profile of plankton concentrates from the 21–56 μm size fraction was complex, dominated by the N-sulfocarbamoyl derivative C2, with levels of other PSP toxins GTX4, NEO, GTX5 (=B1), GTX3, GTX1, STX, C1, and GTX2, in decreasing order of relative abundance. Although no PSP toxin was found systemically in the fish tissues (liver, digestive tract) from this salmon kill event, the detection of Alexandrium cells and low levels of PSP toxins in salmon gills provide evidence that the enhanced mortalities were caused by direct exposure to toxic Alexandrium cells and/or to soluble toxins released during the bloom.     

Phylogenetic relationship of Alexandrium tamiyavanichii (Dinophyceae) to other Alexandrium species based on ribosomal RNA gene sequences

The phylogenetic relationship of the thecate PSP-toxin producing dinoflagellate Alexandrium tamiyavanichii Balech to other species of Alexandrium was studied based on nucleotide sequences of the ITS1, ITS2, 5.8S, 18S and 28S subunits of the ribosomal RNA gene. These are the first such sequences available for A. tamiyavanichii, which is one of the producers of paralytic shellfish poisoning toxins in tropical waters. Based on the nucleotide sequences of the 28S, 18S and 5.8S subunits of the rRNA gene, A. tamiyavanichii grouped together with A. tamarense, A. catenella and A. fundyense. More interestingly, A. tamiyavanichii was most closely affiliated to A. tamarense isolates from Thailand. This result reaffirmed conclusions from previous studies that, for the A. tamarense/fundyense/catenella species complex, geographical origin rather than morphology seems to determine genetic relatedness. Results of this study also suggest that A. tamiyavanichii most probably belongs to the same species complex. Ribosomal RNA gene sequences do not separate the PSP toxin producing from the non-producing species of Alexandrium.     

Six new microsatellite markers for the toxic marine dinoflagellate Alexandrium tamarense

We report the characterization of six new microsatellite loci for the toxic marine dinoflagellate Alexandrium tamarense (North American ribotype), using 56 isolates from a range of locations. The numbers of alleles per locus ranged from five to nine and gene diversities ranged from 0.041 to 0.722. We tested primers for these six loci on other A. tamarense ribotypes and on other Alexandrium species; the results suggest that the primers are specific to A. tamarense isolates belonging to the North American ribotype.     

Development of a qualitative PCR method for the Alexandrium spp. (Dinophyceae) detection in contaminated mussels (Mytilus galloprovincialis)

Paralytic shellfish poisoning (PSP) is a syndrome caused by the consumption of shellfish contaminated with neurotoxins produced by organisms of the marine dinoflagellate genus Alexandrium. A. minutum is the most widespread species responsible for PSP in the Western Mediterranean basin. The standard monitoring of shellfish farms for the presence of harmful algae and related toxins usually requires the microscopic examination of phytoplankton populations, bioassays and toxin determination by HPLC. These procedures are time-consuming and require remarkable experience, thus limiting the number of specimens that can be analyzed by a single laboratory unit. Molecular biology techniques may be helpful in the detection of target microorganisms in field samples. In this study, we developed a qualitative PCR assay for the rapid detection of all potentially toxic species belonging to the Alexandrium genus and specifically A. minutum, in contaminated mussels. Alexandrium genus-specific primers were designed to target the 5.8S rDNA region, while an A. minutum species-specific primer was designed to bind in the ITS1 region. The assay was validated using several fixed seawater samples from the Mediterranean basin, which were analyzed using PCR along with standard microscopy procedures. The assay provided a rapid method for monitoring the presence of Alexandrium spp. in mussel tissues, as well as in seawater samples. The results showed that PCR is a valid, rapid alternative procedure for the detection of target phytoplankton species either in seawater or directly in mussels, where microalgae can accumulate.     

Allelochemical interactions and short-term effects of the dinoflagellate Alexandrium on selected photoautotrophic and heterotrophic protists

The marine dinoflagellate genus Alexandrium (Halim) Balech contains members that produce highly potent phycotoxins (PSP toxins or spirolides) as well as lytic substances and other allelochemicals of unknown structure and ecological significance. One isolate each of six Alexandrium species (A. tamarense, A. ostenfeldii, A. lusitanicum, A. minutum, A. catenella, A. taylori), of the closely related gonyaulacoid dinoflagellate Fragilidium subglobosum, and of the peridinioid Scrippsiella trochoidea were tested in 24 h co-incubation experiments for their short-term deleterious effects on a diversity of marine protists. Both autotrophs (Rhodomonas salina, Dunaliella salina, Thalassiosira weissflogii) and heterotrophs (Oxyrrhis marina, Amphidinium crassum, Rimostrombidium caudatum) were included as target species. All donor isolates except S. trochoidea exhibited lytic effects on at least some target species. Lytic effects were observed with all Alexandrium species, for both whole cell samples and culture filtrate (<10 μm and <0.2 μm). Antibiotic treated cultures with drastically reduced bacterial numbers did not show any general reduction in lytic capacity, therefore direct involvement of extracellular bacteria in allelochemical production is unlikely. Values of EC₅₀, defined as the Alexandrium cell concentration causing lysis of 50% of target cells, differed by two orders of magnitude depending on the donor/target combination, from 3.1 × 10³ cells ml⁻¹ (A. minutum/O. marina) down to 0.02 × 10³ cells ml⁻¹ (A. catenella/D. salina). Within the array of nine donor Alexandrium/target combinations, variable ratios in EC₅₀ values between donor/target combination cannot be explained by quantitative differences in allelochemical production, but rather indicate qualitative differences in the composition of compounds produced by different Alexandrium strains. In conclusion, our study confirms the widespread lytic capacity within the genus Alexandrium, although allelochemical effects are not restricted to this genus. Allelochemical interactions mediated by such lytic substances may be significant in explaining the formation and maintenance of Alexandrium blooms through direct destructive effects on competing algae or unicellular grazers.