亚心型四爿藻在CCCP作用下的光生物产氢的代谢途径

以添加CCCP(羰基氰化物间氯苯腙,Carbonyl cyanide m-chlorophenylhydrazone)的海洋绿藻亚心型四爿藻光生物制氢为研究体系,使用作用于光合系统不同位点的抑制剂研究该藻产氢过程不同时段的代谢途径。结果表明:四爿藻光生物产氢前期电子主要来自PS Ⅱ光解水以及胞内分解代谢,电子经由光合电子传递链传递至氢酶产生氢气;而后期释放的氢气则是通过不依赖光合电子传递链的发酵途径产生。产氢过程厌氧发酵代谢途径主要产物是乙酸、乙醇,其中乙醇代谢途径和氢酶竞争NAD(P)H,不利于氢气的积累。     

基于激光共聚焦扫描显微技术分析激光对扁藻的影响

本文以亚心形扁藻为样品,波长1 341 nm的Nd∶YAP激光为光源,通过激光共聚焦扫描显微技术,研究Nd∶YAP激光辐照亚心形扁藻对亚心形扁藻叶绿体自体荧光强度和叶绿体面积大小的影响。Nd∶YAP激光辐照后的亚心形扁藻通过488 nm Ar^+激光激发获得亚心形扁藻自体荧光图像及其荧光光谱。结果表明,试验中除(10 W,60 s)辐照剂量组外,其余辐照剂量组均提高了亚心形扁藻的自体荧光强度,且所有的辐照剂量组均增大了亚心形扁藻的叶绿体面积。Nd∶YAP激光可刺激亚心形扁藻的叶绿体发育,促进藻细胞的生长,改善叶绿体光合作用的活性。     

CO2加富对两种海洋微绿藻的生长、光合作用和抗氧化酶活性的影响

研究了 CO2 加富对两种海洋微绿藻小球藻和亚心形扁藻的生长、光合作用和抗氧化酶活性的影响。实验结果表明 ,CO2加富 (含 5 0 0 0 μl/ L CO2 的空气 )促进小球藻和亚心形扁藻的生长。但两种藻对 CO2 加富的敏感性不同。CO2 加富对小球藻生物量影响的敏感性小于亚心形扁藻。CO2 加富使两种藻的干重和光合速率显著增加 ;可溶性蛋白含量显著下降 ;但两种藻的 Chla含量和 Car含量与对照相比变化不明显。高浓度 CO2 生长的小球藻和亚心形扁藻的 MDA含量比对照低 ,表明 CO2 升高可以减轻微藻的膜脂过氧化损伤 ,有利于膜脂稳定性的保持 ;在正常浓度 CO2 (36 0μl/ L )条件下 ,抗氧化酶 SOD、POD、CAT、GR的活性因藻种不同而存在很大差异 ,高浓度 CO2 (5 0 0 0μl/ L )培养条件使得这些抗氧化酶中的 SOD、CAT、GR的活性显著降低 ,而POD活性变化则不明显。 CO2 浓度升高可能导致抗氧化酶活性需求的减少 ,从而对藻的氧化损伤具有一定的保护能力。另外 ,光合速率、Chla含量和 Car含量以及抗氧化酶活性因藻种不同而存在很大的差异     

盐生杜氏藻和青岛大扁藻的超低温保存

采用两步法冷冻技术超低浊保存盐生杜氏藻（Ｄｕｎａｌｉｅｌｌａ ｓａｌｉｎｕ（Ｄｕｎａｌ）Ｔｅｏｄ．）和青岛大扁藻（Ｐｌａｔｙｍｏｎａｓ ｈｅｌｇｏｌａｎｄｉｃａ Ｋｙｌｉｎ ｖａｒ．ｔｓｉｇｔａｏｅｎｓｉｓ）。当二甲基亚砚（ＤＭＳＯ）浓度分别为５％和２０％,平衡时间均为ｍｉｎ,预冻温度及保持时间分别为－４０℃,６０ｍｉｎ和－３０℃,３０ｍｉｎ;化冻后分别在０℃和到温下采用慢速稀释法去除ＤＭＳＯ时,     

扁藻多糖的分离分析及其生物活性的初步研究

目的:初步确定亚心型扁藻多糖的理化性质、结构特征及抗肿瘤活性。方法:从培养至平衡期后的亚心型扁藻细胞内分离出乙醇沉淀的多糖级分,经过Sephadex G-150凝胶层析纯化后,利用化学分析及仪器分析进行理化性质和结构特征分析,并通过此多糖对小鼠体内黑色素瘤的抑制作用确定其抗肿瘤活性。结果:扁藻多糖含有氨基和硫酸基,并且含有以葡萄糖为主的多种已知和未知的单糖糖基和糖醛酸,其对小鼠体内黑色素瘤的抑制率为34.2%。结论:此实验结果为扁藻多糖在医疗方面作为抗肿瘤药物的可能性提供了基础依据。     

SILICON UPTAKE BY ALGAE WITH NO KNOWN Si REQUIREMENT. I. TRUE CELLULAR UPTAKE AND pH-INDUCED PRECIPITATION BY PHAEODACTYLUM TRICORNUTUM (BACILLARIOPHYCEAE) AND PLATYMONAS SP. (PRASINOPHYCEAE)1

Phaeodactylum tricornutum Bohlin, the one diatom known to lack a silicon requirement for growth, and the prasinophyte Platymonas sp. are two representatives of a taxonomically diverse group of planktonic algae that have been reported to take up Si without a demonstrable requirement for the element. For both species, removal of Si from solution during growth in batch culture has at least two components; true biological uptake throughout the growth of the culture, and spontaneous inorganic precipitation of a solid silicate phase–probably Mg₂Si₃O₈ (sepiolite)–under the elevated pH conditions that prevail late in batch growth. It is not clear to what extent previous observations of Si uptake by algae without siliceous frustules may be influenced by inorganic, non-cellular precipitation. The kinetics of true cellular uptake of Si are similar in Phaeodalylum and Platymonas, and different from those reported for the Si-requiring diatoms. Uptake follows hyperbolic saturation kinetics in both species, with half-saturation concentrations of 97.4 μM in Phaeodactylum and 80.9 μM in Platymonas, as compared to ca. 1–6 μM in diatoms that form siliceous frustules. Uptake by Phaeodactylum and Platymonas is not substrate-saturated until the dissolved Si concentration of the medium exceeds 200 μM. Concentrations this high do not occur in the surface layer of the ocean, and the kinetics suggest that both species deposit much less silica in nature than they can be induced to deposit in culture.     

Improved hydrogen photoproduction regulated by carbonylcyanide <Emphasis Type="Italic">m</Emphasis>-chlorophenylhrazone from marine green alga <Emphasis Type="Italic">Platymonas subcordiformis</Emphasis> grown in CO<Subscript>2</Subscript>-supplemented air bubble column bioreactor

To develop an integrated process of CO₂-fixation and H₂ photoproduction by marine green microalga Platymonas subcordiformis, the impact of algal cells grown in CO₂-supplemented air bubble column bioreactor was investigated on H₂ photoproduction regulated by carbonylcyanide m-chlorophenylhrazone. Highest cell growth (3.85 × 10⁶ cells ml⁻¹), starch content (0.25 ± 0.08 mg per 10⁶ cells) and hydrogen production (50 ± 3 ml l⁻¹) were achieved at 3% CO₂-supplemented culture, which are respectively 1.4, 2.1, 1.5-fold of the air-supplemented culture. Improved H₂ production correlated well with the increase in starch accumulation. In this process, the algal cells have been recycled for stable H₂ production of 40–50 ml l⁻¹ over five cycles.     

Cryopreservation of Dunaliella salina and Platymonas helgolandica var. tsingtaoensis

Dunaliella salina (Dunal) Teod. and Platymonas helgolandica Kylin var. tsingtaoensis were cryopreserved in liquid nitrogen with a two-step cryopreservation method. With 5% and 20% dimethylsulphoxyde (DMSO) concentration respectively through 30 min equilibrium time, and under -40℃, 60 min and -30℃, 30 min respectively as prefreezing temperature and sustained time, and by using slow dilution method to remove DMSO from the sample at 0℃ and room temperature respectively after sample thawing, D. salina and P. helgolandica var. tsingtaoensis gained the highest survival rates that were 68.5% and 78.3% respectively.     

亚心形扁藻多糖的提取分离纯化及组成研究

以实验室培养的亚心型扁藻为原料,热水提取扁藻多糖。多糖经加热除蛋白、乙醇分级、Sephadex G-50柱层析等一系列纯化步骤后,得到一扁藻多糖(简称PPSc-1)。PPSc-1经醋酸纤维素薄膜电泳和SephadexG-100柱层析的纯度鉴定,组分均一。将多糖PPSc-1用三氟乙酸全水解,然后进行HPAEC-PAD分析,结果表明组成该多糖的单糖为D-半乳糖、D-2-氨基葡萄糖、D-阿拉伯糖、D-鼠李糖和3种未知单糖。各种已知单糖的摩尔比是D-半乳糖∶D-2-氨基葡萄糖∶D-阿拉伯糖∶D-鼠李糖=59.64∶40.9∶18∶1。     

杜氏盐藻和亚心形扁藻在不同接种密度和氮浓度下的细胞群体生长

在氮浓度为1.4、14、和140 mg·L^-1下,对杜氏盐藻(Dunaliella salina)和亚心形扁藻(Platymonas subcordiformis)进行细胞接种比例为10:0、7:3、5:5、3:7和0:10的培养试验,研究不同海洋经济微藻种间混合培养的细胞群体生长效应。结果表明,杜氏盐藻与亚心形扁藻细胞群体的生长随着氮浓度的增加而提高;两种藻在氮浓度分别为14和140mg·L^-1时混合培养的细胞群体生长明显优于单独培养。中、高氮下杜氏盐藻与亚心形扁藻以7:3的接种比例混合时,微藻的细胞群体生物量和胞内物质含量相比单独培养和其他比例均有显著提高,如叶绿素a含量比单独培养分别提高1.17倍和7.77倍;蛋白质含量比单独培养分别提高19.1%和195.3%等。而低氮浓度下,藻的生长受到氮浓度的限制。