不同食物及食物密度对盐蚕豆虫 种群动力学特征的影响

为探究不同食物及食物密度对盐蚕豆虫（Fabrea salina）种群动力学的影响。本文采用商业酵母和杜氏藻（Dunaliella salina）两种不同类型的饲料喂食盐蚕豆虫,探究其种群动力学特征。结果表明,杜氏藻组的盐蚕豆虫具有较高的生长率[（0.78 ± 0.019）/d]、较低的世代时间[（0.89 ± 0.021）d],内禀生长率为1.49/d,米氏常数值为1 121.32;商业酵母组生长率较低[（0.36 ± 0.001）/d],世代时间较长[（1.93 ± 0.007）d],内禀生长率为0.51/d,米氏常数值为2.68。One-way ANOVA检验结果表明,食物及食物密度对盐蚕豆虫的种群生长均有极显著影响（P < 0.01）。以密度为10 × 109 cells/L的杜氏藻投喂,可在短时间内实现盐蚕豆虫的高密度培养和利用,而酵母适用于实验室中盐蚕豆虫的保种工作。     

盐藻对除草剂草丁膦的抗性研究

对分离出的单藻落盐藻进行除草剂草丁膦的抗性实验,液体培养结果显示,野生盐藻对除草剂草丁膦敏感,3.0mg/L剂量的草丁膦能完全抑制盐藻的生长和增殖。     

杜氏盐藻分子生物学最新进展及展望

杜氏盐藻是一种无细胞壁的单细胞双鞭毛真核藻类,是一种十分重要的藻类资源。过去对杜氏盐藻的研究多集中在形态学、耐盐机理及β-胡萝卜素等方面,近年来,随着藻类基因工程的快速发展,本研究课题组及国内外在杜藻盐藻分子生物学方面做了大量工作,现就杜氏盐藻在这一领域的研究进展进行综述,主要是重要功能基因的克隆与分析、杜氏盐藻调控序列的研究以及杜氏盐藻作为宿主表达外源基因等。     

静态荧光光谱法研究杜氏盐藻的生长规律

测量了杜氏盐藻不同生长期的静态荧光光谱,得出了杜氏盐藻生长规律曲线。通过与传统的分光光度计法和血球计数板法研究盐藻生长规律的比较发现,该方法反映的是活盐藻细胞浓度的变化情况,更能反映盐藻实际生长规律;不仅操作简便,灵敏度高,而且可以实现远距离非接触测量。     

人canstatin基因转化新型生物反应器－杜氏盐藻(Dunaliella salina)的初步研究

本文采用RT-PCR技术从人的胎盘组织中克隆canstatin基因,定向连接到表达载体pUΩ上,然后与筛选标记bar盒连接得到真核表达载体pUΩ-Can-Bar。采用玻璃珠转化法将该表达载体转化杜氏盐藻（以下简称盐藻）,通过草丁膦固体平板筛选得到转化株,进而对转化株进行阳性鉴定。PCR结果显示,在盐藻转化株中均能够扩增出约700 bp特异的条带,而在阴性对照中没有扩增出该条带。Southern blot结果进一步证明人canstatin基因已经整合到盐藻细胞的基因组中。此外,本文对盐藻转化株的遗传稳定行进行了分析,结果表明canstatin基因能够在转化藻株中稳定遗传。人canstatin转基因盐藻株的成功制备为利用盐藻反应器大规模生产人canstatin蛋白提供了实验依据,为及早实现canstatin蛋白在治疗肿瘤上的临床应用提供了前期工作基础。     

A phylogenetic study of the genus Haligena (Halosphaeriales, Ascomycota)

The genus Haligena (Halosphaeriales, Ascomycota), with two accepted species, is encountered frequently in marine habitats, especially on wood in temperate regions. Phylogenetic analyses of Haligena elaterophora (type species) and H. salina were undertaken, with partial large subunit ribosomal DNA sequences, to determine their relationships with other closely related genera in the order. The genus was shown to be polyphyletic within the Halosphaeriales with the type species forming a basal clade to the order. Haligena salina constituted a sister clade with weak support of Neptunella longirostris in all analyses. Haligena elaterophora and H. salina differ significantly in the nature of their ascospore appendages: wider, more sticky and strap-like in H. elaterophora and spoon-shaped at the point of attachment; in H. salina they are longer and narrower, finely drawn out filaments. A new genus, Morakotiella, is introduced to accommodate H. salina.     

Distribution of the brine shrimps Parartemia zietziana Sayce and Artemia salina (L.) along a salinity and oxygen gradient in a South Australian saltfield

SUMMARY. The seasonal distribution of Parartemia zietziana and Artemia salina was studied in a South Australian saltfield. P. zietziana occurred alone at salinities from 112 to 214%‰ and A. salina occurred alone at salinities above 285%‰; the two species overlapped in the range 214 to 285%‰. Respiration experiments indicated that A. salina had a lower 'critical' oxygen concentration than P. zietziana , apparently due to the presence of haemoglobin in A. salina . This may result in an adaptive advantage at high salinity and low dissolved oxygen.     

NaCl-induced phosphorylation of light harvesting chlorophyll a/b proteins in thylakoid membranes from the halotolerant green alga, Dunaliella salina

Light could induce phosphorylation of light harvesting chlorophyll a/b binding proteins (LHCII) in Dunaliella salina and spinach thylakoid membranes. We found that neither phosphorylation was affected by glycerol, whereas treatment with NaCl significantly enhanced light-induced LHCII phosphorylation in D. salina thylakoid membranes and inhibited that in spinach. Furthermore, even in the absence of light, NaCl and several other salts induced LHCII phosphorylation in D. salina thylakoid membranes, but not in spinach thylakoid membranes. In addition, hypertonic shock induced LHCII phosphorylation in intact D. salina under dark conditions and cells adapted to different NaCl concentrations exhibited similar LHCII phosphorylation levels. Taken together, these results show for the first time that while LHCII phosphorylation of D. salina thylakoid membranes resembles that of spinach thylakoid membranes in terms of light-mediated control, the two differ with respect to NaCl sensitivity under light and dark conditions.     

高浓度钾抑制杜氏盐藻生长的生理机制

在含１ｍｏｌ／ＬＮａＣｌ的杜氏盐藻（Ｄｕｎａｌｉｅｌａｓａｌｉｎａ（Ｄｕｎａｌ）Ｔｅｏｄ．）培养液中加入５０ｍｍｏｌ／Ｌ以上的ＫＣｌ可观察到Ｋ＋对杜氏盐藻生长有明显的抑制作用,而当ＫＣｌ达１００ｍｍｏｌ／Ｌ时,杜氏盐藻的生长被完全抑制。另一方面,当培养液中缺乏Ｋ＋时,杜氏盐藻的生长也被显著抑制。在正常培养条件下,伴随着杜氏盐藻的生长,培养液的ｐＨ由８左右升高至１０左右,而高浓度Ｋ＋则显著抑制杜氏盐藻培养液ｐＨ的升高;而在培养液ｐＨ为７．０至１０．０的范围内,不同ｐＨ对杜氏盐藻的生长无明显影响。将杜氏盐藻在高浓度Ｋ＋条件下预处理１２ｈ以上,杜氏盐藻的光合放氧速率显著下降,光合速率下降的程度与Ｋ＋浓度的高低和预处理的时间长短呈正相关。高浓度Ｋ＋处理也引起杜氏盐藻叶绿素含量的显著下降。对经高浓度Ｋ＋预处理的杜氏盐藻的光合放氧速率与培养液中ｐＨ变化同时进行测定的结果表明,Ｋ＋抑制杜氏盐藻光合速率的同时也显著抑制了光照条件引起的培养液ｐＨ的上升。实验结果表明,Ｋ＋抑制杜氏盐藻光合作用以及抑制杜氏盐藻生长与Ｋ＋影响跨盐藻质膜的质子运输之间可能存在一定关系。     

Physiological Mechanisms of Growth inhibition by Concentrated Potassium in Dunaliella Salina

It was observed in our preliminary experiments that the growth of Dunaliella salina (Dunal) Teed. cultured in medium containing 1 mol/L NaC1 was almost completely inhibited by the addition of 100 mmol/L KC1. This study was focused on elucidating the physiological mechanisms by which high K+ inhibits D. salina growth. Under the control conditions, the pH of the medium rapidly increased from 8 to 10 along with the growth of D. salina. However, addition of 100 mmol/L KCI significantly inhibited the increase of medium pH. The results suggested that the growth of D. salina may require a low environmental of H + concentration or be related to the H + transport into the D. salina cells. Interestingly, D. salina cultured in various media with different pH buffered with 40 mmol/L Tris-HC1 (or Tris-NaOH) did not show any significant difference in the growth rates. This result brings up the question on the previous hypothesis that Na+/H+ antiport plays a major role in Na + extrusion in D. salina. The photosynthetic rate of D. salina was not inhibited immediately following the addition of high K+ in the reaction medium, but it was significantly inhibited after the pretreatment of algae with high K+ for 12 hours or longer. The results from simultaneous measurements of O2 evolution of D. salina and the changes in pH of the medium revealed that the inhibitory effect of high K + on D. salina growth was somehow associated with K+ effect on pH changes in the medium. The high K+ treatment of D. salina also resulted in significant decrease of chlorophyll contents in the algae. It is concluded that the inhibitory effects of high K + on photosynthesis of D. salina may, at least partially, account for the growth-inhibition of D. salina growth by high K+; the inhibitory effects of high K+ on D. salina photosynthesis may result from the influence of K + on H + transport across the plasma membranes of D. salina cells.     

Effects of Prorocentrum donghaiense and Alexandrium catenella on the material transfer in a simulated marine food chain

The biochemical composition of Prorocentrum donghaiense was analyzed and the effects of P. donghaiense and Alexandrium catenella on the transport of materials through a simulated marine food chain were investigated. The results showed that the content of phenylalanine, histidine and lysine in P. donghaiense was obviously lower than that in other dietary microalgae. Fed with P. donghaiense solely, the gross conversion efficiencies (GCEs) of A. salina increased gradually when the algal densities were lower than 4 × 104 cells/ml, and decreased gradually at higher densities. When fed with the mixture of P. donghaiense and the diatom Nitzschia. closterium, A. salina preferred grazing on P. donghaiense to grazing on N. closterium, and the GCEs of A. salina decreased with the increasing density of P. donghaiense. Exposed to A. catenella, A. salina lost weight and no Chlorophyll a was detected in the guts, which indicated that A. salina did not ingest the algal cells. When the re-suspended cells and cell-free medium of A. catenella were mixed with N. closterium or P. donghaiense, respectively, the grazing and GCEs of A. salina were all diminished. Consequently, the large-scale blooms of P. donghaiense and A. catenella in the East China Sea could adversely affect zooplankton owing to insufficient food or nutrition, and therefore impact the material transfer efficiency through the food chain.     

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。     

杜氏盐藻促生菌株的分离与鉴定

拟通过探究藻际微生物对微藻生长及代谢产物积累的影响,筛选出促进微藻生长的促生菌株。以杜氏盐藻(Dunaliella salina)Ds-SXYC-2为试材,分离鉴定盐藻藻际环境中的共生菌株,进一步构建藻菌(1∶1)共培养体系、测试盐藻生长及代谢产物积累等表型。结果显示,从杜氏盐藻藻际环境分离获得5株共生菌株,经16S rDNA分子鉴定,属于3个菌属。菌株B1与B2为涅斯捷连科氏菌(Nesterenkonia),菌株B3与B4为盐单胞菌(Halomonas),菌株B5为海杆菌(Marinobacter)。5株共生菌株对杜氏盐藻的生长均有促进作用,菌株B3能显著促进杜氏盐藻生长及代谢产物的积累。共培养15 d后,杜氏盐藻生物量达到2.3 g/L,比对照组增加了28.9%,叶绿素a的含量达到4.61 mg/L,比对照组增加了36.3%,β-胡萝卜素比对照组提高了56.4%。盐藻多糖、蛋白质、总脂含量分别比对照组增加了34.8%、71.2%和37.6%。菌株B3盐单胞菌可以作为促进杜氏盐藻生长及代谢产物累积的优势菌株,进一步构建共培养体系可应用于杜氏盐藻的商业生产。     

海洋经济微藻混合培养与单独培养下的生长比较

海洋微藻可以广泛应用在水产养殖、食品加工、医药保健、环境保护和生物制能等各种行业,具有非常好的开发利用前景.目前,如何突破海洋微藻培养过程中细胞生物量低下等瓶颈,提高微藻的细胞密度,以低成本、高效率开发利用海洋微藻资源成为了国内外学者关注的焦点.论文以三角褐指藻、亚心型扁藻和杜氏盐藻3 种典型经济海洋微藻为研究材料,在实验室条件下研究了它们两两混合培养与各自单独培养条件下的细胞生长情况,探讨海洋微藻混合培养在促进微藻整体细胞生长方面的可能性.结果显示,三角褐指藻和杜氏盐藻混合培养在生长前9 天的OD680 高于三角褐指藻或杜氏盐藻分别单独培养的OD680 ,而随着试验时间的延长,混合培养条件下的OD680 与单独培养三角褐指藻的OD680 相似;就三角褐指藻和亚心型扁藻混合培养的OD680而言,在整个生长时期均高于单独培养亚心型扁藻的OD680 ,但低于单独培养三角褐指藻的OD680 ;不同的是,杜氏盐藻和亚心型扁藻混合培养下的OD680 在生长第6 天后高于单独培养杜氏盐藻或单独培养亚心型扁藻的OD680 .研究结果表明,混合培养三角褐指藻和杜氏盐藻或混合培养杜氏盐藻和亚心型扁藻具有一定程度促进微藻细胞生长的潜力.研究结果将为经济海洋微藻的高密度培养及其高附加价值活性物质的开发利用提供一个崭新的研究方向.     

Identification and characterization of a new strain of the unicellular green alga Dunaliella salina (Teod.) from Korea

The unicellular green alga Dunaliella salina is a halotolerant eukaryotic organism. Its halophytic properties provide an important advantage for open pond mass cultivation, since D. salina can be grown selectively. D. salina was originally described by E. C. Teodoresco in 1905. Since that time, numerous isolates of D. salina have been identified from hypersaline environments on different continents. The new Dunaliella strain used for this study was isolated from the salt farm area of the west coastal side of South Korea. Cells of the new strain were approximately oval- or pear-shaped (approximately 16-24 microm long and 10-15 microm wide), and contained one pyrenoid, cytoplasmatic granules, and no visible eyespot. Although levels of beta-carotene per cell were relatively low in cells grown at salinities between 0.5 to 2.5 M NaCl, cells grown at 4.5 M NaCl contained about a ten-fold increase in cellular levels of beta-carotene, which demonstrated that cells of the new Korean strain of Dunaliella can overaccumulate beta- carotene in response to salt stress. Analysis of the ITS1 and ITS2 regions of the new Korean isolate showed that it is in the same clade as D. salina. Consequently, based on comparative cell morphology, biochemistry, and molecular phylogeny, the new Dunaliella isolate from South Korea was classified as D. salina KCTC10654BP.     

营养盐浓度对航天搭载盐藻生长及胞外多糖含量的影响

比较了培养液中不同营养盐浓度对“神舟5号”搭载盐藻(Dunaliella salina)和非搭载盐藻的生长及胞外多糖积累的影响,发现经“神舟5号”搭载后盐藻最适营养盐浓度发生了变化。非搭载盐藻培养液中最佳单因子组合为:CaC l2200 mg/L、MgC l2500 mg/L、KNO31 000 mg/L、KH2PO455 mg/L。搭载盐藻培养液中最佳单因子组合为:CaC l2250 mg/L、MgC l2500 mg/L、KNO31 000 mg/L、KH2PO415 mg/L。搭载和非搭载盐藻胞外多糖累积的最佳单因子组合相同:CaC l2、MgC l2、KNO3、KH2PO4分别为250、2 000、500、15 mg/L,但搭载盐藻胞外多糖的分泌明显高于非搭载盐藻。     

新型生物反应器——杜氏盐藻研究进展

转基因植物作为生物反应器生产外源物质已成为基因工程领域的研究热点之一 ,而杜氏盐藻 (Dunaliellasalina)作为新型生物反应器生产外源蛋白具有独特的优点 ,就盐藻这一生物反应器的特点、存在问题和开发应用前景等的最近研究进展作一简要综述。     

杜氏盐藻（Dunaliella salina）基因工程的研究现状及应用前景

杜氏盐藻（简称盐藻）作为新型的生物反应器,成为藻类基因工程的研究热点之一。利用基因工程手段对盐藻进行遗传改造以生产外源物质是目前研究的重要领域。本文从盐藻相关基因的克隆、cDNA文库的建立、基因组文库的构建、筛选标记的确立和外源基因的表达等五个方面全面概述了国内外盐藻基因工程的研究进展,特别是对最新的研究结果进行了综述,并对基因工程技术在盐藻深入研究中的应用做了前景展望。     

Neuronal connectivity patterns in the compound eyes of Artemia salina and Daphnia magna (Crustacea: Branchiopoda)

The neuronal types and patterns in the visual system of the species Artemia salina and Daphina magna have been studied with the Golgi method and electron microscopy. The lamina contains five classes of neurons: photoreceptor axons, monopolar, centrifugal, tangential and amacrine neurons. The terminals of the receptor axons are distributed in two (A. salina) or three (D. magna) layers. The dilated terminals have an extensive and wide array of fine branches. One axon from each ommatidium bypasses the lamina and terminates in the medula in A. salina. A. salina has four types of monopolar neurons, two of which are stratified, whereas in D. magna only two types are found, one of which is bistratified. Tangential T-neurons connect the lamina with the protocerebrum. D. magna has in addition one tangential T-neuron connecting both the lamina and the medulla with the protocerebrum. In both species monopolar-type centrifugal neurons connect the medulla and the lamina, whereas that of A. salina has a wide laminar distribution. Both species also have amacrine cells in the lamina. The medulla contains, besides those shared with the lamina, transmedullary neurons (two types in A. salina), amacrine cells and neurons originating in the protocerebrum. "Cartridge"-type synaptic compartments are lacking in the investigated species, although a periodic arrangement is discernible in the distal portion of the lamina of A. salina. The receptors from three types of specialized contacts in Artemia, one of which involves a dyad. D. magna has only one-to-one synapses. Neurosecretory fibres are absent in A. salina.