塔玛亚历山大藻对氮和磷的吸收及其生长特性

参照塔玛亚历山大藻(Alexandrium tamarense)赤潮爆发时的物理条件,以f／2加富的人工海水为培养基,设定了不同的氮、磷水平,研究了在室内批量培养条件下,塔玛亚历山大藻对无机氮、磷的吸收和无机氮、磷对塔玛亚历山大藻细胞生长的影响．结果表明,3种氮浓度条件下,塔玛亚历山大藻的比生长速率几乎没有差异,但低氮(0．0882mmol·L-1)条件下,藻细胞的生物量最低;中氮(0．882mmol·L-1)条件下,藻细胞具有最大的生物量,分别比高氮(2．646mmol·L-1)和低氮下增加44．7％和53．6％．随着培养基中磷浓度的升高,藻细胞生物量也升高,在高磷(0．108mmol·L-1)条件下达到最大值17200cell·ml-1,但在中磷(0．036mmol.L-1)条件下藻细胞具有最大的比生长速率．藻细胞对氮、磷的吸收速率与生长状态有密切关系,氮、磷限制条件下生长的藻细胞对氮、磷有快速的吸收．研究显示,低的N／P比有利于塔玛亚历山大藻的生长分裂,对数生长后期适当补氮则有利于其生物量的积累．     

Fe3+对浮游颤藻生长和光合作用的影响

考察了浓度为0—30mmol/L的范围内,Fe3 对浮游颤藻(Oscillatoria planctonicaWoloszynska)的生长、生化组成和光合作用的影响。结果表明,当Fe3 浓度小于10nmol/L时,浮游颤藻的生长以及叶绿素和蛋白质的合成均受到明显的抑制,对其补铁后这种抑制能够得到一定程度的缓解。当Fe3 浓度达到10mmol/L时,最大生物量与比生长速率分别是不加铁时的3倍和4倍。富铁条件下藻细胞光饱和的光合作用速率(Pm)、暗呼吸速率(Rd)和表观光合作用效率(α)显著大于缺铁条件,而光补偿点Ic及饱和光强Ik则低于缺铁条件。结果显示,铁是浮游颤藻生长的重要限制因子。     

重金属Zn2+胁迫下米氏凯伦藻(Karenia mikimotoi)的生长生理响应研究

采用室内培养试验方法, 以米氏凯伦藻(Karenia mikimotoi)为生物材料, 设置不同浓度梯度的重金属Zn2+(0、1、5、10、15和20 mg•L-1), 主要测定藻细胞密度、光合色素、光合效率、抗氧化酶类、丙二醛(malondialdehyde, MDA)等相关指标, 探讨重金属Zn2+胁迫下米氏凯伦藻(Karenia mikimotoi)的生长和生理特征。结果发现, 在1和5 mg•L-1的Zn2+浓度下, 米氏凯伦藻细胞依然保持较好生长繁殖, 表明其具有一定的耐受性, 而随着重金属Zn2+浓度的提高, 细胞生长受到毒害抑制。光合色素含量呈现动态变化, 试验结束时(96 h)叶绿素a、叶绿素b和胡萝卜素含量有各自不同的变化趋势, 最大光能转化效率(Fv/Fm)表现出先升后降的趋势。Zn2+浓度为10 mg•L-1时, 超氧化物歧化酶(superoxide dismutase, SOD)活性显著高于对照; 过氧化氢酶(catalase, CAT)活性呈现出先上升后下降的趋势, 且5、10、15和20 mg•L-1 Zn2+浓度下米氏凯伦藻的过氧化氢酶(CAT)活性均显著高于对照; 10、15 mg•L-1 Zn2+浓度下米氏凯伦藻的总抗氧化能力(total antioxidant capacity, T-AOC)显著高于对照, 而20 mg•L-1 Zn2+浓度下的显著低于对照。丙二醛(MDA)呈现出随着Zn2+浓度提高而增加的趋势, 5、10、15和20 mg•L-1Zn2+浓度下米氏凯伦藻的丙二醛(MDA)均显著高于对照。结果可为了解重金属对海洋微藻的毒性作用提供数据参考。     

CO2对微拟球藻(Nannochloropsis sp.)利用有机碳和光合作用的影响

CO2浓度提高时,微拟球藻吸收醋酸钠的速率增加2倍。混养生长的藻细胞最大光合作用速率、光合作用效率、无机碳半饱和常数和无机碳饱和的光合作用速率均显著低于光自养条件下生长的。     

赤潮异弯藻在铁限制条件下的光谱特性

由活体吸收光谱可见,赤潮异弯藻在叶绿素c靠近红光区的吸收峰处,由铁丰富条件下的632nm向蓝漂移2nm．由于类胡萝卜素相对于叶绿素a的比值在铁限制的细胞内增大,因而受铁限制的细胞活体吸收光谱在480nm左右类胡萝卜素的吸收峰处增加了一个吸收峰．赤潮异弯藻细胞低温荧光发射光谱在685nm处有一明显的发射峰。与铁丰富条件(10μmol.L-1)相比,缺铁(5nmol·L-1)和低铁(100nmol·L-1)细胞在685nm处的荧光得率分别升高了2倍和1．4倍．补铁48h后荧光得率则明显降低。表明细胞在铁限制条件下存在大量能量耗散,降低了细胞光合作用效率．     

水华鱼腥藻生长与光合作用对大气CO2浓度升高的响应

 为了探讨大气CO2浓度升高对水华藻类的影响,利用水华鱼腥藻(Anabena flos_aquae)作为实验材料,研究了大气CO2浓度加倍对其生长和光合作用的影响,结果显示大气CO2浓度升高导致水华鱼腥藻的生物量、光饱和光合速率、光合效率和光系统II的光化学效率（Fv/Fm）明显提高,但对暗呼吸速率和光饱和点没有明显影响。CO2加倍条件下藻细胞光合作用对无机碳的亲和力降低,表明其利用HCO-3的能力受到抑制。     

N、P营养盐对海洋卡盾藻（Chattonella marina）生长的影响

在实验室条件下,设置不同的N、P浓度,研究N、P双因子限制(N:5-500ug·L-1,P:0.74-74ug·L-1,N:P=15)及单因子限制(N:500ug·L-1,P:0.74-741ug·L-1和P:74ug·L-1,N:5-500ug·L-1)对海洋卡盾藻生长的影响.结果表明:在高N、P浓度(N:500ug·L-1,P:74ug·L-1)条件下海洋卡盾藻具有相对较高的比生长率(O.788/d),稳定期持续时间较长,最大细胞密度可达8850 cells/ml.N、P限制能明显抑制海洋卡盾藻的生长,而N限制对海洋卡盾藻生长影响更大,N限制组的比生长率和稳定期细胞密度均明显低于P限制组和N、P双因子限制组.结果说明海洋卡盾藻生长对N变化更为敏感,但随着海洋污染的加剧,海水中N含量持续上升,卡盾藻可迅速爆发性增长并引发赤潮,这也许是近年来我国沿海卡盾藻赤潮频繁发生的重要原因之一.     

不同起始细胞浓度对Chlorococcum pamirum室外生长的影响

实现微藻产油工业化生产最有效的方法是利用自然光对微藻进行培养。本文在室外条件下研究了不同起始细胞浓度对Chlorococcum pamirum生长的影响,结果表明:起始细胞浓度(OD550)为0.02时比生长速率最高(0.309d-1);起始密度为1.5时生长速率最高(69mg·L-1d-1)。     

平板式光生物反应器中紫球藻培养条件的优化

研究了平板式光生物反应器中紫球藻(Porphyridium cruentumNaegeli)的培养条件,运用均匀设计法对光照强度、通气速率、装液量、接种密度以及pH等影响紫球藻生长的因素进行优化,获得了在平板式光生物反应器中培养紫球藻的最佳条件:光照强度10 000 lx、通气速率350 L.h-1、装液量6 L、藻细胞接种密度1.1×106mL-1、pH9.0。在最佳条件下藻体的生物量产率和生物量产量分别达到0.431 g.L-1.d-1和3.240 g.L-1,最大生长速率达0.652 g.L-1.d-1,胞外多糖含量高达0.665 g.L-1。另外,在培养过程中隔天补充培养液有利于紫球藻生物量的增加和胞外多糖的产生。     

氮磷营养因子对赤潮异弯藻生长的影响

研究了N、P营养浓度对赤潮异弯藻(Heterosigma akashiwo)生长的影响.结果表明,该藻的生长速率与N、P营养因子浓度的关系符合Monod公式.在NO₃^--N浓度达到7.5 mg·L^-1时,赤潮异弯藻开始生长;浓度为3.75～75 mg·L^-1时,赤潮异弯藻的比生长速率与NO₃^--N浓度成正比关系.N营养充足时,赤潮异弯藻的最大生长速率μ_m-n=0.3475·d^-1,K_s-n=18.91 mg·L^-1.PO₄^--P浓度为0～1.0 mg·L^-1时,赤潮异弯藻的比生长速率与P浓度成正比关系;P营养充足时,赤潮异弯藻的最大生长速率μ_m-p=0.3024·d^-1,K_s-p=0.4086 mg·L^-1.N/P达到25后藻细胞浓度达到最大,表明N/P为25时最适合赤潮异弯藻生长.赤潮异弯藻最适合在N 37.5～225.0 mg·L^-1、P 5.0～50.0 mg·L^-1、N/P=25条件下生长.     

Growth and photosynthesis limitation of marine red tide alga Skeletonema costatum by low concentrations of Zn2+

The specific growth rate, cell final yields and extracellar carbonic anhydrase activity of the red tide alga Skeletonema costatum increased with increasing concentrations of Zn2+ from 0 to 12 pM, but decreased when Zn2+ was over 24 pM. However, cells grown under high concentrations of Zn2+ had higher activities of intracellular carbonic anhydrase than those grown under low concentrations of Zn2+. Chlorophyll a-specific light-saturated photosynthetic rate (P(Chla)), dark respiration rate (R(chla)) and apparent photosynthetic efficiency (alpha(chla)) significantly increased with increasing concentrations of Zn2+ from 0 to 3 pM, but decreased when increasing concentrations of Zn2+ from 3 to 66 pM. Photorespiration is the lowest when cells cultured in 3 pM Zn2+. The results suggest physiological activity of Skeletonema costatum is very sensitive to the prevailing concentration of Zn2+.     

Photosynthetic response of Chlamydomonas reinhardtii to short-term storage on ice in darkness. Dependence of the response on growth conditions

The effect of storage of the unicellular green alga Chlamydomonas reinhardtii (strain 137+) in the pelleted state in darkness on ice (0.2–0.5°C) (further simply “SPDI-treatment”) on its photosynthetic and respiratory activities was studied. To this end, the steady-state rates of O₂ exchange in darkness (dark respiration) and under saturating light (apparent photosynthesis) as well as the induction periods (IP) of apparent photosynthesis were measured at 25°C in the SPDI-untreated and SPDI-treated for the period from ～0.5 to ～30 h algal cells. In contrast to expectations, the SPDI-treatment consistently affected the rate and IP of photosynthesis depending on the physiological state of C. reinhardtii. Dark respiration was affected by the SPDI-treatment as well. However, in absolute values the respiratory changes were much less than the photosynthetic ones, and they were insufficiently reproducible. The SPDI-treatment affected photosynthesis most significantly in high-CO₂-grown cells (cells grown at 5% CO₂ in white light). The rate of photosynthesis in these cells declined quasi-exponentially as a function of time during the SPDI-treatment with a t _1/2 ～1.5 h and finally became by about 60% lower than that before the SPDI-treatment. This decline of photosynthesis was accompanied by continuous and essential increase in the photosynthetic IP. The SPDI-induced photosynthetic changes in high-CO₂-grown cells resulted from the firm disfunction of the photosynthetic apparatus. After switch from growth at 5% CO₂ in white light to growth at ～0.03% CO₂ (air) in white, blue, or red light, the alga gradually transited to a physiological state, in which the negative effects of the SPDI-treatment on the rate and IP of photosynthesis became weak and absent, respectively. Remarkably, this transition was faster in blue (≤5 h) than in white and red light (>10 h). Similar changes in the response of the alga to the SPDI-treatment occurred when high-CO₂-grown cells (5% CO₂, white light, 26°C) were incubated in darkness (air, 24–26°C) for 20–25 h. The results of study were analyzed in the light of literature data relating to the effects of CO₂ concentration, darkness, and light quality on carbohydrates in plant organisms. The analysis led to suggestion that there is connection between the negative effect of the SPDI-treatment on C. reinhardtii and nonstructural carbohydrates presented in the alga: the more carbohydrates contain the alga, the more extensive inactivation of the photosynthetic apparatus occurs in it during its storage in the dense (pelleted) state in darkness on ice.     

Biomass yields of Chlorella from iron (Y x/Fe) in iron-limited batch cultures

The maximum biomass in iron-limited photosynthetic batch cultures of chlorella increased as the logarithm of the iron concentration. The growth yield from iron (Y _x/Fe) showed a marked inverse relation to the specific growth rate. The maximum biomass yield, g dry biomass/g iron consumed, was 7.5x10³ with specific growth rate 0.108 h^-1; the minimum was 0.79×10³ with specific growth rate 0.145 h^-1. The maximum specific growth rate in the exponential phase of Fe limited cultures varied as the initial Fe concentration. Fe-limited growth made the cells adhere to a glass surface.Abbreviation O.D. optical density     

Cell growth and enzyme synthesis of a mutant of Arthrobacter sp. (DSM 3747) used for the production of L-amino acids from D,L-5-monosubstituted hydantoins.

A microorganism with the ability to form L-tryptophan from D,L-5-(3-indolyl-methyl)hydantoin (D,L-5-IMH) was isolated and identified as Arthrobacter sp. (DSM 3747). After isolation of a mutant with high tryptophan production activity but low tryptophan degradation, cultural conditions were optimized to achieve high amounts of biomass with good specific activities concerning the enzymatic hydantoin-cleaving reactions. The ability of the microorganism to perform these bioconversions was found to be inducible by D,L-5-IMH as well as to be dependent on the presence of Mn2+. The highest specific D,L-5-IMH-cleaving activity of the cells was observed in the exponential phase of growth. The addition of yeast extract to the mineral salts medium was found to be essential for obtaining biomass concentrations of about 25 g l-1 cell dry mass by bioreactor cultivations. In order to obtain a constantly high growth rate, feeding of the C-source was pO2-controlled. The inducer D,L-5-IMH had to be continuously fed to prevent a decline of the L-tryptophan-forming enzyme activities, because it was subjected to degradation with the enzymes induced and higher concentrations of D,L-5-IMH aggravated the growth significantly. The synthesis of the enzymes was also inducible, when inducer and Mn2+ were not added until the late growth phase. Using this process, the consumption of D,L-5-IMH was reduced remarkably. So, under these conditions biomass concentrations of 25 g l-1 cell dry weight with a specific enzymatic activity of 0.20 mmol g-1 h-1 (tryptophan per dry mass per time) could be obtained within 13 h. Using 1 g l-1 of the chemically modified inducer D,L-5-(3-indolylmethyl)-3-N-methylhydantoin, which was not degradable by the microorganisms, a biomass concentration of 28 g l-1 cell dry weight with a specific activity of 0.34 mmol g-1 h-1 (tryptophan per dry mass per time) could be obtained within 28 h.     

重金属诱导拟南芥原生质体DNA 损伤的单细胞凝胶电泳检测

以拟南芥原生质体为实验体系, 研究不同浓度的3种重金属离子对拟南芥原生质体的毒性和DNA损伤的差异。结果表明, 用1-5 mmol.L-1的Zn2+、Cd2+ 和Cu2+分别处理的拟南芥原生质体, 2 小时内活力逐渐下降, 并表现出明显的浓度依赖性;与相同浓度的Cd2+ 和Cu2+ 相比, Zn2+对拟南芥原生质体活力的影响程度较小, 表现出较低的毒性。单细胞凝胶电泳检测发现,用0.1-0.8 mmol .L-1的Zn2+、Cd2+ 和Cu2+ 分别处理拟南芥原生质体30 分钟, 以OTM值表示的原生质体DNA损伤量随重金属离子浓度的增加而递增; 相同浓度(0.5 mmol.L-1)的3种重金属离子相比, Zn2+对原生质体的遗传毒性明显低于Cu2+ 和Cd2+。综合原生质体活力和DNA损伤的单细胞凝胶电泳检测结果, 发现Zn2+对拟南芥原生质体的遗传毒性较低, 而Cd2+ 和Cu2+的遗传毒性较高。本研究建立的拟南芥原生质体实验体系, 结合运用单细胞凝胶电泳技术, 能够快速、灵敏地检测重金属对植物细胞的遗传毒性。     

Influence of ultraviolet radiation, copper, and zinc on microcystin content in Microcystis aeruginosa (Cyanobacteria)

Cyanobacterial toxin production is allied to some unknown trigger resulting in the production of toxins such as microcystin. We hypothesize that microcystins serve as metal ligands to control bioavailability and toxicity of ambient metals. Since ultraviolet radiation (UVR) promotes photo-oxidation of organic metal ligands and influences trace metal bioavailability, the present study aimed to investigate the influence of UVR, Cu, and Zn on specific growth rates, biomass, photosynthetic capacity, and microcystin content in Microcystis aeruginosa. Two toxigenic strains of Microcystis were cultivated using either Lake Erie filtered water or a chemically defined medium, with realistic concentrations of Cu and Zn combined with natural or artificial UVR exposure. Cu was more toxic than Zn on the basis of free ion concentration of trace metals in synthetic medium, although in Lake Erie water total added Zn (10 nM) or Zn plus Cu (10 nM) had a more detrimental effect on biomass and specific growth rate. Natural UVR delivered at 25% ambient levels caused no decrease on the parameters measured (chlorophyll-a, photosynthetic rate), yet artificial levels of UVR (up to 5.9 μmol UVB photons m⁻² s⁻¹) negatively affected biomass and specific growth rate. Cellular levels of microcystin (per unit chlorophyll-a) were concomitant with specific growth rather than being triggered in response either of these stressors (UVR, Zn, and Cu) alone or in combination, in agreement with a purported constitutive production of microcystins.     

光照强度和氮水平对白三叶幼苗生长与光合生理特性的影响

采用植物生长箱溶液培养方式,对白三叶幼苗进行了不同光强(2个水平)和氮浓度(5个水平)处理,探讨其生长、生物量和光合生理特征对生境变化的响应.结果表明:两种光强下白三叶幼苗茎和叶生物量随氮素浓度呈先升高后降低,而根系生物量和根冠比则随氮素浓度增高而降低.光照强度降低使白三叶幼苗根、茎、叶和整株生物量分别降低67.8%、29.9%、42.5%和45.2%;低光处理使幼苗的根冠比显著下降,而比叶面积(SLA)明显提高.幼苗根系体积随氮素浓度增高而降低,高生长光强根系体积显著高于低生长光强下的白三叶.幼苗根系表面积、根系长度和根系直径随氮素浓度增加呈先增加后降低趋势,两种不同生长光强下幼苗根系长度和根系直径差异显著,而根系表面积差异不明显.白三叶叶片光合速率(Pn)随氮素浓度增加呈先增加后降低趋势,高生长光强白三叶Pn显著高于低生长光强下的白三叶.两种生长光强间叶片气孔导度(Gs),胞间CO2浓度(Ci)和蒸腾速率(Tr)无显著差异,但氮素浓度对叶片Gs、Ci和Tr均有显著影响.光、氮及其交互作用对白三叶幼苗生长发育产生了显著影响,光照不足和氮缺乏都将导致白三叶幼苗生长减弱,但幼苗对这些不利环境具有较强的调节和适应能力.     

Elevated CO2 and plant nitrogen-use: is reduced tissue nitrogen concentration size-dependent?

Plants often respond to elevated atmospheric CO₂ levels with reduced tissue nitrogen concentrations relative to ambient CO₂-grown plants when comparisons are made at a common time. Another common response to enriched CO₂ atmospheres is an acceleration in plant growth rates. Because plant nitrogen concentrations are often highest in seedlings and subsequently decrease during growth, comparisons between ambient and elevated CO₂-grown plants made at a common time may not demonstrate CO₂-induced reductions in plant nitrogen concentration per se. Rather, this comparison may be highlighting differences in nitrogen concentration between bigger, more developed plants and smaller, less developed plants. In this study, we directly examined whether elevated CO₂ environments reduce plant nitrogen concentrations independent of changes in plant growth rates. We grew two annual plant species. Abutilon theophrasti (C₃ photosynthetic pathway) and Amaranthus retroflexus (C₄ photosynthetic pathway), from seed in glass-sided growth chambers with atmospheric CO₂ levels of 350 mol·mol^–1 or 700 mol·mol^–1 and with high or low fertilizer applications. Individual plants were harvested every 2 days starting 3 days after germination to determine plant biomass and nitrogen concentration. We found: 1. High CO₂-grown plants had reduced nitrogen concentrations and increased biomass relative to ambient CO₂-grown plants when compared at a common time; 2. Tissue nitrogen concentrations did not vary as a function of CO₂ level when plants were compared at a common size; and 3. The rate of biomass accumulation per rate of increase in plant nitrogen was unaffected by CO₂ availability, but was altered by nutrient availability. These results indicate that a CO₂-induced reduction in plant nitrogen concentration may not be due to physiological changes in plant nitrogen use efficiency, but is probably a size-dependent phenomenon resulting from accelerated plant growth.