氮磷营养盐对微氏海链藻细胞生化组成的影响

探讨了高营养盐条件下氮浓度及氮磷摩尔比[n(N):n(P)]异动对微氏海链藻(Thalassiosiraweissflogii)的细胞碱性活性基团含量、细胞干质量、细胞形态及细胞体中碳水化合物、蛋白质、叶绿素含量,即对细胞生命力和表面吸附力的影响。结果表明,n(N):n(P)=16时,叶绿素、碳水化合物和蛋白质含量最高,生长状况及生命力最佳,有利于金属吸收,n(N):n(P)偏离16,各组份含量均减少。碱性活性基团和藻细胞大小,当n(N):n(P)=8时最大,表面吸附金属能力最强;n(N):n(P)=64时最小,不利于金属的吸附。氮磷摩尔比对微氏海链藻细胞体主动吸收和生物吸附金属的影响不同。     

氮、磷对金藻的增殖效应

本文通过室内培养试验，研究了水体中氮、磷含量变化及氮、磷交互作用对金藻增殖的影响，并比较了不同形态的氮盐对该藻增殖的反应。试验得出该藻生长的氮氨（氯化铵）最适浓度水平为150μmol－N／L，相应的无机磷的最适浓度水平为10μmol-P/L；有机氮（尿素）的最适浓度水平为250μmol－N／L，相应的无机磷最适度水平为5μmol－P／L。氨氮和尿素的试验中，金藻的生长趋势相似，但是相对应浓度下，氨氮的增殖效应大于尿素。氮的形态不同时，藻类对同一种磷的利用也可能产生差异。     

尿素对三种海洋微藻生长影响的初步研究

鉴于人们对有机氮影响微藻生长的研究较少,以及尿素在池塘养殖中的不断应用,研究了尿素对3种海洋微藻生长的影响情况。结果表明,尿素对这3种微藻的生长影响极显著,最适生长的浓度值也不同：最适宜增殖的氮、磷浓度依次为,赤潮异弯藻：氮300μmol／L,磷10μmol／L：海链藻：氮100μmol/L,磷5μmol／L;隐藻：氮300μmol／L,磷10μmol／L。还对N／P值的情况进行了探讨,提出该比值可能和氮态有关,并指出了经常被忽略的几种情况。     

微绿球藻对氮和磷营养盐需求的研究

通过单因子实验和正交实验方法，研究了对虾高位池一种优良藻株微绿球藻（Nannochloris oculata)对N和P营养盐需求，结果表明：微绿球藻在NO3-N浓度为28．30mg/L和PO4-P浓度为2．076mg/L时，比增长率最大值（μmax)出现最佳值，微绿球藻以各种起始密度培养和小规模培养的均能得到较好的生长效果，μmax可较好地反映微藻种群对多因子的适应性和在对虾池塘中的竞争能力。     

不同氮、磷浓度及配比对铜藻(Sargassum horneri)幼苗生长的影响

采用铜藻(Sargassum horneri)幼苗为实验对象,分别以Na NO3和Na H2PO4为氮源和磷源,研究了不同氮磷质量浓度及氮磷配比对铜藻幼苗生长的影响。进行了氮、磷单因子实验、双因子实验以及不同氮磷配比实验,实验时间为8d。结果表明:氮和磷对铜藻幼苗生长影响极显著(P0.01),且当氮、磷的质量浓度分别为8mg/L、0.4mg/L时,铜藻幼苗的特定生长率最大;交互作用影响不显著(P0.05),不同质量浓度的氮为主效应;不同氮磷质量浓度比影响极显著(P0.01),且当氮磷比为10:1时,铜藻幼苗的特定生长率最大。研究结果为铜藻幼苗培育过程中营养盐的合理调控提供了理论依据。     

长江干流营养盐通量的初步研究

分别于1988年2月（冬季）和1986年6月（夏季）利用比色法对长江干流上游至河口水中营养盐进行测定，根据所测定的营养盐含量和长江径流量计算营养盐通量。结果表明，冬季重庆至河口长江水中NO3－N，NH4-N，TIN，PO4-P和SiO3-Si的平均浓度分别为52.2±66μmol／L，51.8±16.9μmol／L，105.3±11.4μmol／L，0.55±0．06μmol／L和75.2±23.6μmol／L.夏季NO3-N,NH4-N,TIN和SiO3-Si的平均浓度分别为69.0±17.0μmol／L,4.0±1.7μmol／L，73.3±15.6μmol／L和55.8±16.4μmol／L。冬季营养盐通量（除NO2－N外）自上游至下游逐渐增加，它们主要来自中、下游流域。夏季NO3－N，TIN和SiO3－Si通量从上游至下游也有明显的增加趋势，NO3－N和TIN，上游和中、下游几乎各占一半，SiO3-Si主要来自中、下游。夏季NO3－N，TIN，PO4－P和SIO3－Si通量明显高于冬季。     

不同氮磷比对中肋骨条藻生长特性的影响

本文对在不同氮磷比（1：1，4：1，16：1，80：1，160：1）的培养条件下，中肋骨条藻的生长和营养生理特征进行了研究。结果表明：中肋骨条藻生长和生理状态受氮磷化的影响比较明显。在N／P＝16：1的状态下，其生长速度最快，细胞数量最高；在氮磷比大于16状态下的生长速度要优于氮磷比小于16的营养状态，说明其生长主要受到氮的限制。叶绿素a浓度受氮磷比的影响与细胞的生长基本相一致。相反，藻细胞内碳水化合物和蛋白质的合成和积累量在氮磷比≤16的状态下高于氮磷比大于16的状态。     

蒽、菲、芘、■混合液对菲律宾蛤仔抗氧化酶活性的影响

以菲律宾蛤仔（Ruditapes philippinarum）为研究对象，在实验生态条件下采用不同浓度的蒽（Fluoranthene）、菲（Phenaphthene）、芘（Pyrene）、[艹屈]（chrysene）混合液进行染毒实验，研究菲律宾蛤仔体内超氧化物歧化酶（superoxide dismutase，SOD）、过氧化氢酶（catalase，CAT）和谷胱苷肽过氧化物酶（glutathione peroxidase，GPx）的剂量-效应关系和时间-效应关系。实验的3种混合液浓度为5μg／L（低浓度组），50μg/L（中浓度组），500μg／L（高浓度组）。结果表明，在低浓度混合液下（5μg／L），CAT比SOD和GPx更快受到诱导；4种多环芳烃混合污染物对SOD、CAT和GPx活性的影响均为先诱导后抑制的变化过程。     

南日岛海域溶解态Cu、Pb、Cd含量及其与营养盐的关系

本文首次报道了福建南日岛海域溶解态Cu、PB、Cd的含量，探讨了它们与营养盐的关系。1990年5月溶解态Cu、Pb、Cd的平均含量分别为0．84、0．230、0．023μg／dm3；1990年10月分别为0. 78、0．290、0. 033μg／dm3。其5月溶解态Cu与无机氮N（NO3-＋NO2-＋NH4 ）线性回归的相关式为Cu（μg／dm3）＝-0. 789＋0．328N（μmol／dm3），相关系数r＝0．853，原子比△Cu：△N＝5．17×10－3：1。     

渤海湾西南部典型站位营养盐限制特性的加富培养实验研究

2010年10月,对渤海湾西南部海域典型站位表层水体进行了模拟现场的营养盐加富培养实验。初始状态下,培养水样中溶解无机氮浓度为20.68μmol/L,磷酸盐浓度0.24μmol/L,硅酸盐浓度4.58μmol/L,叶绿素a浓度为1.05μg/L,浮游植物细胞密度为1 080 cells/L。通过改进实验设计,研究了该水样的营养盐限制类型、水样中浮游植物对不同氮磷比以及不同硝酸盐添加方式的生态响应。实验结果表明,在单一添加营养盐的各组中,添加磷酸盐的1-3组叶绿素a浓度和浮游植物细胞密度的增长状况最显著,1-3组叶绿素a浓度峰值为空白对照组1-1组的2.48倍,达到营养盐全加组1-5组同期浓度的48%,其细胞密度峰值为1-1组的1.66倍,达到1-5组同期密度的72%,该水样为磷限制。在实验条件下,浮游植物的增长在总体上随着氮磷比的降低而增大,最适宜的氮磷比为5-15左右,略低于Redfield比值16。硝酸盐的连续性添加比一次性添加更有利于浮游植物的生长,暗示了低浓度长期持续性氮污染可能会比高浓度冲击性氮污染更有效地刺激浮游植物的增长,从而造成更严重的生态问题,而此时用以往的一次性添加培养实验可能会低估浮游植物的增长潜力。     

纳米TiO2 对海洋生源要素含量及威氏海链藻生长的影响

探讨不同质量浓度纳米TiO2(0,4,8,12,16,20 mg/L)对海洋生源要素(N,P,Si,Fe)含量及威氏海链藻(Thalassiosira weissflogii)生长的影响。实验结果表明:随纳米二氧化钛浓度增大,对海洋生源要素的吸附率有不同程度的提高,海洋生源要素含量下降,对磷和铁的影响最为明显;纳米二氧化钛吸附对氮磷比和硅磷比影响很大,氮磷比为68~126,硅磷比为74~135,而对硅氮比影响很小基本维持在1。纳米二氧化钛对威氏海链藻生长有明显抑制,并存在剂量—效应关系,与海洋生源要素含量影响存在相关性。     

硝基苯和间苯二酚对3 种海洋微藻的毒理效应

通过研究硝基苯和间苯二酚对海洋微藻的毒理效应,旨在提示化工废水污染对水环境破坏的严重性,揭示海洋微藻类净化废水的潜在应用。本试验用塔玛亚历山大藻(Alexandrium tamarense)、海链藻(Thalassiosira weissflogii)和绿色巴夫藻(Pavlova viridis)为供试藻种,以微藻生长量及叶绿素 a 的变化为参数,研究不同质量浓度的硝基苯和间苯二酚对3种海洋微藻的毒理效应。结果表明：硝基苯对塔玛藻和巴夫藻的生长具有一定的抑制作用,质量浓度为12mg/L时抑制率分别为22.9%和20.04%,但对海链藻的生长在一定程度上有促进作用。间苯二酚对海链藻和巴夫藻的生长具有抑制作用,质量浓度为12mg/L 时其抑制率分别为26.11%和23.6%,对塔玛亚历山大藻的生长有一定的促进作用。对塔玛亚历山大藻和巴夫藻而言,在硝基苯质量浓度为3mg/L 时,叶绿素 a 含量均达到最低,其叶绿素 a含量分别为对照组的68.6%和50.9%,对于海链藻,硝基苯对其叶绿素a的影响波动不大。间苯二酚对3种海洋微藻叶绿素 a 含量的影响为绿色巴夫藻>海链藻>塔玛亚历山大藻,其叶绿素 a 含量分别是对照组的1.1%,24.9%,88%。     

天津近岸浮游植物群落对海洋酸化和硝酸盐加富的响应

为了评估海洋酸化和富营养化耦合作用对近海浮游生态环境的影响,本研究以天津市近岸海域浮游植物群落的生物地球化学指标为研究对象,分别采用一次性及连续培养的方式模拟自然水华及稳态条件,探究其对二氧化碳(CO₂)和硝酸盐浓度变化及二者耦合作用的响应。实验条件设置如下:1)对照:二氧化碳分压p(CO₂)40.53 Pa、无硝酸盐添加;2)酸化:p(CO₂)101.3 Pa、无硝酸盐添加;3)加N:p(CO₂)40.53 Pa、添加硝酸盐50 μmol·L^–1;4)酸化加N:p(CO₂)101.3 Pa、添加硝酸盐50 μmol·L^–1。实验结果表明,硝酸盐加富比酸化更加显著地促进浮游植物群落总叶绿素(Chl a)生物量及颗粒有机碳(POC)和颗粒有机氮(PON)积累,酸化和加N使浮游植物群落粒径大小升高。连续培养实验表明,酸化和N加富对Chl a、生物硅(BSi)、PON浓度、PON与颗粒有机磷(POP)比值(N/P)、POC与BSi比值(C/BSi)及沉降速率有协同交互作用,对POP和POC浓度及POC与PON比值(C/N)有拮抗性交互作用。在一次性培养后,酸化显著降低了浮游植物群落的沉降速率;而在连续培养后,酸化和N加富使浮游植物群落沉降速率显著升高。这些结果表明酸化和N加富对与近岸浮游植物相关的生物地球化学循环及在不同生长阶段的种群碳沉降存在不同的潜在影响及交互效应。     

Effect of macronutrient enrichment on the size distribution, sorption, and bioconcentration factor of iron by coastal phytoplanktonic diatoms

The influences of macronutrient enrichment on iron absorption, adsorption, and the bioconcentration factor (BCF) of iron by coastal diatoms were examined. In addition, the distribution of different iron size fractions in seawater in relation to two diatom species exposed to nutrient enrichment over an extended period (6 days for Thalassiosira weissflogii, and 4 days for Skeletonema costatum), was investigated. Iron concentrations were measured of seven size fractions: particles (>0.4 μm), colloidal particles (0.4 μm–100, 100–50, 50–30, 30–10, 10–3 kDa), and soluble species (<3 kDa).The absorption, adsorption, uptake, BCF of iron by the diatoms, and the iron species distribution in seawater were affected by the diatom species, as well as the nitrate (N) and phosphate (P) concentration. The addition of P could affect the iron internalization strategy. The content of soluble iron species was positively correlated with the amount of iron absorption by T. weissflogii, but it was not suitable for S. costatum.     

Surfactant production by marine phytoplankton

Electrochemical methods based on adsorption of organic molecules at the mercury electrode-solution interface were used to investigate surfactant production by marine phytoplankton. Six species of marine phytoplankton, representing the classes of Bacillariophyceae, Haeptophyceae, Chlorophyceae and Cryptophyceae, were studied in batch cultures.Our experimental results showed that surfactants were produced in culture media by healthy exponential growing cells. The measured response was found to depend on the particular species and the age of the culture.Total surfactant content in culture media generally increased with cell density, while surfactants per cell showed an inverse relation to cell density. However, we found that in Cryptomonas culture medium, during the exponential growth, excretion of the insoluble surfactant material per cell was independent of cell concentration.In addition to culture experiments, surfactant activity at several northern Adriatic stations was measured during various stages of phytoplankton bloom. It was concluded that a significant part of surfactant activity in a seawater column is due to phytoplankton production.     

An Ecosystem Model Including Nitrogen Isotopes: Perspectives on a Study of the Marine Nitrogen Cycle

We have developed an ecosystem model including two nitrogen isotopes (¹⁴N and ¹⁵N), and validated this model using an actual data set. A study of nitrogen isotopic ratios (δ¹⁵N) using a marine ecosystem model is thought to be most helpful in quantitatively understanding the marine nitrogen cycle. Moreover, the model study may indicate a new potential of δ¹⁵N as a tracer. This model has six compartments: phytoplankton, zooplankton, particulate organic nitrogen, dissolved organic nitrogen, nitrate and ammonium in a two-box model, and has biological processes with/without isotopic fractionation. We have applied this model to the Sea of Okhotsk and successfully reproduced the δ¹⁵N of nitrate measured in seawater and the seasonal variations in δ¹⁵N of sinking particles obtained from sediment trap experiments. Simulated δ¹⁵N of phytoplankton are determined by δ ¹⁵N of nitrate and ammonium, and the nitrogen f-ratio, defined as the ratio of nitrate assimilation by phytoplankton to total nitrogenous nutrient assimilation. Detailed considerations of biological processes in the spring and autumn blooms have demonstrated that there is a significant difference between simulated δ¹⁵N values of phytoplankton, which assimilates only nitrate, and only ammonium, respectively. We suggest that observations of δ ¹⁵N values of phytoplankton, nitrate and ammonium in the spring and autumn blooms may indicate the ratios of nutrient selectivity by phytoplankton. In winter, most of the simulated biogeochemical fluxes decrease rapidly, but nitrification flux decreases much more slowly than the other biogeochemical fluxes. Therefore, simulated δ¹⁵N values and concentrations of ammonium reflect almost only nitrification. We suggest that the nitrification rate can be parameterized with observations of δ¹⁵N of ammonium in winter and a sensitive study varying the parameter of nitrification rate.     

Iron regeneration and organic iron(III)-binding ligand production during in situ zooplankton grazing experiment

To elucidate iron regeneration and organic iron(III)-binding ligand formation during microzooplankton and copepod grazing on phytoplankton, incubation experiments were conducted in the western subarctic Pacific. During 8 days of dark incubation of ambient water and that amended with plankton concentrate, dissolved iron and organic iron(III)-binding ligands accumulated, approximately proportionally to the decrease in chlorophyll a. The observed increases in dissolved iron concentration were much greater than those expected from the consumption of phytoplankton biomass and previously reported Fe:C value of cultured algal cells, suggesting resolution from colloidal or particulate iron adsorbed onto the algal cell surface. When copepods were added to the ambient water, organic iron(III)-binding ligands accumulated more rapidly than in the control receiving no copepod addition, although consumed phytoplankton biomass was comparable between the two treatments. Bioassay experiment using filtrates collected from the incubation experiment showed that organic ligands formed during microzooplankton grazing reduced the iron bioavailability to phytoplankton and suppressed their growth. Moreover, picoplankton Synechococcus sp. and Micromonas pusilla were more suppressed by the organic ligands than the diatom Thalassiosira weissflogii. In conclusion, through microzooplankton and copepod grazing on phytoplankton, organic iron(III)-binding ligands as well as regenerated iron are released into the ambient seawater. Because the ligands lower iron bioavailability to phytoplankton through complexation and the degree of availability reduction varies among phytoplankton species, grazing by zooplankton can shift phytoplankton community structure in iron-limited waters.     

室内培养硏究硝酸盐对中肋骨条藻生长的影响

中肋骨条藻是一种广温、广盐性的浮游硅藻，并且多次在长江口及其他海域形成赤潮，对海洋生态环境造成严重危害，因此引起国内、外赤潮研究者的广泛关注。不少学者对中肋骨条藻种群的生态、生理特点展开研究(刘东艳等，2002；黄文祥等，1989；邹景忠等，1989；李铁，1990，2000)。营养盐是海洋浮游植物所必需的成分，海水中某种营养盐含量过低往往对浮游植物生长形成限制(Myers et al.，1981；Brian，1986；胡明辉等，1989)。海水营养盐含量过高则易形成富营养化，可进一步引发赤潮(周名江，2001)。硝酸盐是海洋浮游植物所必需的营养物质之一，它直接影响着浮游植物的生长、繁殖等生物活动(李铁，2000；Ryther et al.，1971)。研究海水中硝酸盐浓度和N/P对浮游藻类生长的影响将有助于我们了解高营养化与赤潮发生之间的关系。本文对在不同营养结构条件下，中肋骨条藻的生长速率、培养介质中的pH和溶解有机碳(DOC)进行了研究。     

Seasonal variations in nutrients and chlorophyll-a concentrations in the Northern east China sea

Nutrients, chlorophyll-a, particulate organic carbon (POC), and environmental conditions were extensively investigated in the northern East China Sea (ECS) near Cheju Island during three seasonal cruises from 2003 to 2005. In spring and autumn, relatively high concentrations of nitrate (2.6~12.4 μmol kg^-1) and phosphate (0.17~0.61 μmol kg^-1) were observed in the surface waters in the western part of the study area because of the large supply of nutrients from deep waters by vertical mixing. The surface concentrations of nitrate and phosphate in summer were much lower than those in spring and autumn, which is ascribed to a reduced nutrient supply from the deep waters in summer because of surface layer stratification. While previous studies indicate that upwellings of the Kuroshio Current and the Changjiang (Yangtze River) are main sources of nutrients in the ECS, these two inputs seem not to have contributed significantly to the build-up of nutrients in the northern ECS during the time of this study. The lower nitrate:phosphate (N:P) ratio in the surface waters and the positive correlation between the surface N:P ratio and nitrate concentration indicate that nitrate acts as a main nutrient limiting phytoplankton growth in the northern ECS, contrary to previous reports of phosphate-limited phytoplankton growth in the ECS. This difference arises because most surface water nutrients are supplied by vertical mixing from deep waters with low N:P ratios and are not directly influenced by the Changjiang, which has a high N:P ratio. Surface chlorophyll-a levels showed large seasonal variation, with high concentrations (0.38~4.14 mg m^-3) in spring and autumn and low concentrations (0.22~1.05 mg m^-3) in summer. The surface distribution of chlorophyll-a coincided fairly well with that of nitrate in the northern ECS, implying that nitrate is an important nutrient controlling phytoplankton biomass. The POC:chlorophyll-a ratio was 4~6 times higher in summer than in spring and autumn, presumably because of the high summer phytoplankton death rate caused by nutrient depletion in the surface waters.     

Carbon and nitrogen isotope composition of particulate organic matter in relation to mucilage formation in the northern Adriatic Sea

Carbon and nitrogen stable isotope ratios of particulate organic matter (POM) were studied approximately weekly during spring and summer 2003 and 2004 in the Gulf of Trieste (northern Adriatic Sea) in order to track the temporal variations and differences between two years. In parallel, particulate organic carbon (POC) and particulate nitrogen (PN), phytoplankton biomass (chlorophyll a), and N and P nutrients were monitored. All studied parameters, especially N and P nutrients and chlorophyll a, showed higher concentrations and larger variability in spring 2004. As a consequence the macroaggregates were produced in late spring 2004. The C and N isotope composition of POM was not directly linked to phytoplankton biomass dynamics. The δ¹³C_POC values covaried with temperature. In 2004, δ¹³C_POC variations followed the δ¹⁵N_PN values as well as the δ¹³C_DIC values which were probably more dependent on the photosynthetic use of ¹²C. Variations in δ¹⁵N_POM values were most probably the consequence of variations in N nutrient sources used in phytoplankton assimilation. The significant correlation between δ¹⁵N_PN values and nitrate concentrations in 2004 implies intense nitrate assimilation in the presence of higher nitrate concentration. This suggests nitrate as the key nutrient in the »new primary production«, later producing macroaggregates with a mean δ¹³C and δ¹⁵N values of − 19‰ and 5‰, respectively. A low fractionation factor ε, < 1‰, lower than that reported in other marine and lacustrine systems, was found probably to be a consequence of distinct phytoplankton species, i.e. several classes of autotrophic nanoflagellates, and specific growth conditions present in the Gulf of Trieste. The tentative use of C isotope composition of POM revealed a higher contribution of allochthonous organic matter in 2004 compared to 2003 due to higher riverine inflow.