滇池水华蓝藻铜锈微囊藻和绿色微囊藻的生长生理特性及毒素分析

从滇池分离纯化了两种常见水华微囊藻即铜锈微囊藻和绿色微囊藻。在常规培养条件下,两种藻类在对数生长期的生长速率μ值分别为0.61和0.63;早期生长的抑制光强不大于100μmol m~(-2)s~(-1)。铜锈微囊藻主要产生3种微囊藻毒素:MYCST-RR,MYCST-YR和MYCST-LR,绿色微囊藻产生的主要微囊藻毒素为[Dha~7]-MYCST-RR,和[Dha~7]-MYCST-LR,另含有少量的[Dha~7]-MYCST-YR。在低光强15μE m~(-2)s~(-1)时,毒素含量每毫克干重细胞达到3.127μg微囊藻毒素,当光强达到100μE m~(-2)s~(-1)时,毒素含量降低到每毫克干重细胞1.971μg;光强对毒素形成的影响受到温度的调节,而温度对毒素形成的影响不大。探讨了两种微囊藻细胞在不同光照强度下叶绿素荧光比值Fv/Fm的变化,此比值的变化可以间接反映细胞受外界光照强度抑制程度。     

溶藻细菌FS1的溶藻效果与机制初探

近年来,由水体富营养化引发的蓝藻水华频繁暴发,对水体生态系统平衡产生了重大影响,给人类健康也带来严重威胁。生物法除藻具有高效性、环境友好等优点,因此,如果能获得具有较高溶藻效率的溶藻细菌,选择生物法除藻更为理想。从菏泽一富营养化池塘分离得到1株溶藻细菌FS1,经16S rDNA测序分析鉴定为芽胞杆菌属。实验以铜绿微囊藻为研究对象,采用血球计数板法计算反应前后藻细胞的浓度,对不同生长阶段溶藻细菌FS1的溶藻效果进行了探究。停滞期、对数期、稳定期和衰亡期的除藻率分别为7.1%、24.3%、57.0%和45.5%,结果表明,处于稳定期的FS1对铜绿微囊藻的去除效果最佳。细菌溶藻方式的研究结果表明,溶藻细菌是通过分泌溶藻物质间接溶解藻细胞。     

Controlling the Growth of Microcystis Using Surged Artificial Aeration

This paper investigates the effect of lake mixing, due to artificial hypolimnetic aeration, on the succession and ecological composition of selected phytoplankton species in Tegeler See, Berlin. Special attention is given to Microcystis, a nuisance bloom-forming blue-green algae and its competitor (in this lake) Ceratium, a dinoflagellate. Due to the installation configuration, the aerators frequently destratified the lake, especially when the stratification was weak. Five years representing three different operating schemes of the 15 aerators (continuous aeration, non-aeration and surge aeration) in this lake were used to determine possible aeration strategies in controlling Microsystis. In order to ease correlation of the mixing status in the lake with its yearly successions of phytoplankton growth a non-dimensional parameter called the Lake number was utilised. This parameter represents a balance between: i) forcing due to wind and aerator discharge and ii) potential energy acquired from the stratification of the lake. The results indicate that surged operation of the aerators is effective in suppressing massive growth of Microcystis. Due to their ability to adapt to the mixing/stability state of the water column, prolonged aeration or prolonged stable stratified conditions have little effect in controlling this algae.     

微囊藻毒素合成酶基因的PCR检测方法

针对微囊藻毒素合成酶基因簇的核酸序列,筛选特异性引物,探索一种适用于自然水样中微囊藻产毒潜能检测的全细胞PCR方法。经灵敏度测试表明,这种PCR方法的检测下限相当于100cells。该方法不需要提取基因组DNA,检测所需水样量少,具有操作简便、快速、成本低、灵敏度高等优点,能应用于水库等饮用水源水体中具有产毒潜能的微囊藻的检测。     

Effects of arsenate on the growth and microcystin production of Microcystis aeruginosa isolated from Taiwan as influenced by extracellular phosphate

Arsenic pollution and eutrophication are both prominent issues in the aquaculture ponds of Taiwan. It is important to study the effects of arsenic on algal growth and toxin production in order to assess the ecological risk of arsenic pollution, or at least to understand naturally occurring ponds. The sensitivity of algae to arsenate has often been linked to the structural similarities between arsenate and phosphate. Thus, in this study we examined the effects of arsenate (10⁻⁸ to 10⁻⁴ M) on Microcystis aeruginosa TY-1 isolated from Taiwan, under two phosphate regimes. The present study showed that M. aeruginosa TY-1 was arsenate tolerant up to 10⁻⁴ M, and that this tolerance was not affected by extracellular phosphate. However, it seems that extracellular phosphate contributed to microcystin production and leakage by M. aeruginosa in response to arsenate. Under normal phosphate conditions, total toxin yields after arsenate treatment followed a typical inverted U-shape hormesis, with a peak value of 2.25 ± 0.06 mg L⁻¹ in the presence of 10⁻⁷ M arsenate, whereas 10⁻⁸ to 10⁻⁶ M arsenate increased leakage of ∼75% microcystin. Under phosphate starvation, total toxin yields were not affected by arsenate, while 10⁻⁶ and 10⁻⁵ M arsenate stimulated microcystin leakage. It is suggested that arsenate may play a role in the process of microcystin biosynthesis and excretion. Given the arsenic concentrations in aquaculture ponds in Taiwan, arsenate favors survival of toxic M. aeruginosa in such ponds, and arsenate-stimulated microcystin production and leakage may have an impact on the food chain.     

The effects of temperature and nutrients on the growth and dynamics of toxic and non-toxic strains of Microcystis during cyanobacteria blooms

In temperate latitudes, toxic cyanobacteria blooms often occur in eutrophied ecosystems during warm months. Many common bloom-forming cyanobacteria have toxic and non-toxic strains which co-occur and are visually indistinguishable but can be quantified molecularly. Toxic Microcystis cells possess a suite of microcystin synthesis genes (mcyA–mcyJ), while non-toxic strains do not. For this study, we assessed the temporal dynamics of toxic and non-toxic strains of Microcystis by quantifying the microcystin synthetase gene (mcyD) and the small subunit ribosomal RNA gene, 16S (an indicator of total Microcystis), from samples collected from four lakes across the Northeast US over a two-year period. Nutrient concentrations and water quality were measured and experiments were conducted which examined the effects of elevated levels of temperatures (+4 °C), nitrogen, and phosphorus on the growth rates of toxic and non-toxic strains of Microcystis. During the study, toxic Microcystis cells comprised between 12% and 100% of the total Microcystis population in Lake Ronkonkoma, NY, and between 0.01% and 6% in three other systems. In all lakes, molecular quantification of toxic (mcyD-possessing) Microcystis was a better predictor of in situ microcystin levels than total cyanobacteria, total Microcystis, chlorophyll a, or other factors, being significantly correlated with the toxin in every lake studied. Experimentally enhanced temperatures yielded significantly increased growth rates of toxic Microcystis in 83% of experiments conducted, but did so for non-toxic Microcystis in only 33% of experiments, suggesting that elevated temperatures yield more toxic Microcystis cells and/or cells with more mcyD copies per cell, with either scenario potentially yielding more toxic blooms. Furthermore, concurrent increases in temperature and P concentrations yielded the highest growth rates of toxic Microcystis cells in most experiments suggesting that future eutrophication and climatic warming may additively promote the growth of toxic, rather than non-toxic, populations of Microcystis, leading to blooms with higher microcystin content.     

白屈菜红碱对铜绿微囊藻生长和光合系统的影响

为了阐明白屈菜红碱(Chelerythrine)对铜绿微囊藻(Microcystis aeruginosa)生长及光合系统的影响, 研究了白屈菜红碱胁迫下铜绿微囊藻M. aeruginosa NIES-843生长、细胞色素含量及叶绿素光诱导荧光动力学变化. 结果显示, 当白屈菜红碱浓度10 g/L时, M. aeruginosa NIES-843的生长受到显著抑制. 通过线性回归分析, 白屈菜红碱对M. aeruginosa NIES-843生长50%抑制浓度(EC50)为(30.621.32) g/L. 当白屈菜红碱浓度为160 g/L时, M. aeruginosa NIES-843单位细胞内叶绿素a (Chl. a)和类胡萝卜素含量均显著低于对照. Chl. a光诱导荧光动力学分析结果显示, 白屈菜红碱胁迫下单位反应中心吸收的光能(ABS/RC)、单位反应中心捕获的用于还原QA的能量(TR0/RC)及单位反应中心捕获的用于电子传递的能量(ET0/RC)均受到显著抑制. 光合系统Ⅱ(PSⅡ)能量分配比率参数分析结果显示, 白屈菜红碱能显著抑制光合系统反应中心电子供体侧电子传递.       

GENETIC ADAPTATION AND ACCLIMATION OF PHYTOPLANKTON ALONG A STRESS GRADIENT IN THE EXTREME WATERS OF THE AGRIO RIVER–CAVIAHUE LAKE (ARGENTINA)1

We tested if different adaptation strategies were linked to a stress gradient in phytoplankton cells. For this purpose, we studied the adaptation and acclimation of Dictyosphaerium chlorelloides (Naumann) Komárek et Perman (Chlorophyta) and Microcystis aeruginosa (Kütz.) Kütz. (Cyanobacteria) to different water samples (from extremely acid, metal‐rich water to moderate stressful conditions) of the Agrio River–Caviahue Lake system (Neuquén, Argentina). Both experimental strains were isolated from pristine, slightly alkaline waters. To distinguish between physiological acclimation and genetic adaptation (an adaptive evolution event), a modified Luria‐Delbrück fluctuation analysis was carried out with both species by using as selective agent sample waters from different points along the stress gradient. M. aeruginosa did not acclimate to any of the waters tested from different points along the stress gradient nor did D. chlorelloides to the two most acidic and metal‐rich waters. However, D. chlorelloides proliferated by rapid genetic adaptation, as the consequence of a single mutation (5.4 × 10^?7 resistant mutants per cell per division) at one locus, in less extreme water and also by acclimation in the least extreme water. It is hypothesized that the stress gradient resulted in different strategies of adaptation in phytoplankton cells from nonextreme waters. Thus, very extreme conditions were lethal for both organisms, but as stressful conditions decreased, adaptation of D. chlorelloides cells was possible by the selection of resistant mutants, and in less extreme conditions, by acclimation.     

A GROWTH ADVANTAGE FOR MICROCYSTIN PRODUCTION BY MICROCYSTIS PCC7806 UNDER HIGH LIGHT1

Batch cultures of both Microcystis PCC7806 and a mcyA^? knockout mutant (MT) of PCC7806 were cultured at three different light intensities and five media treatments, so as to vary cellular N:C ratios and concentrations and sampled daily over 5 d for analysis of microcystin concentration, cell numbers, and residual nitrate in the growth medium. A competitive survival advantage was noted at a high‐light level (37 μmol photons · m^?2 · s^?1), where the toxic strain survived while the nontoxic strain became chlorotic. A strong correlation (r² = 0.91, P < 0.001, N = 22) between microcystin concentration and growth rate was observed at high‐light conditions. No advantage was observed at optimal or low‐light conditions, and media composition had no significant effect on the relationship between toxicity and survival at high‐light conditions. These data suggest a possible role for microcystin in protection against photooxidation.     

Intracellular phosphorus metabolism of Microcystis aeruginosa under various redox potential in darkness

Phosphorus metabolism of Microcystis aeruginosa was studied under gradient redox potential from 252 mV to –70 mV in darkness. The release of phosphorus occurred in all the treatments, and this process was accelerated in darkness when the redox potential was lowered. Low redox potential in darkness stimulated the accumulation of polyphosphate (PolyP) and the degradation of polyglucose. The synthesis of PolyP delayed the decrease of intracellular orthophosphate. The death of M. aeruginosa was slowered when the redox potential was low in darkness. The accumulation of PolyP under low redox potential in the dark was very important to M. aeruginosa for endurance through the unfavorable growth conditions for maintaining phosphorus concentration, energy storage, and other physiological functions. The ability to accumulate PolyP in the dark and negative redox potential may be of considerable advantage in the low-light, organically rich, and low-redox habitats.