不同氮源对微小亚历山大藻生长和毒素产生的影响

通过尿素、氯化铵、酵母浸出粉和硝酸钠等氮源对微小亚历山大藻(Alexandrium minutum)生长及毒素产生的影响研究,分析了微小亚历山大藻对不同氮源利用状况的差异.结果表明,在氮饥饿条件下,加入硝酸钠和酵母浸出粉能显著促进微小亚历山大藻的生长;高浓度的氯化铵在加入后对微小亚历山大藻有一定的毒性效应,表现为生长停滞,但毒性效应在5 d后消失,并得到与添加硝酸钠及酵母浸出粉相似的增长速率0.21 d-1;添加尿素对微小亚历山大藻的生长没有显著促进作用.在四种氮源中,尿素对微小亚历山大藻毒素产生的刺激作用也最弱,在稳定期每个细胞藻细胞毒素含量维持在6.00~8.00 fmol;添加硝酸钠、氯化铵和酵母浸出粉的藻细胞在稳定期毒素含量分别达到11.85,12.86和14.64 fmol.硝酸钠和氯化铵刺激藻毒素产生的效果比酵母浸出粉更为直接.四种含氮营养盐对微小亚历山大藻毒素组成的影响都很小.     

胶州湾菲律宾蛤仔生长特征研究

为对胶州湾菲律宾蛤仔增养殖业的可持续发展提供技术支持,2004年5～9月,通过对胶州湾菲律宾蛤仔进行定点采样调查和生物学特性测定,分析研究了菲律宾蛤仔的生长特征.结果表明：近几年胶州湾菲律宾蛤仔的底播增殖,苗种平均体重0.26g、壳长11.1mm;1～3龄期间个体生长速度较快,1～2龄、2～3龄,体重分别增长3.88g和4.02g;1～2龄生物量增长最快,2～3龄由于死亡率提高,使生物量增长缓慢;壳长、壳高、壳宽与体重关系式分别为y=0.000 2x^3.053 3,y=0.000 4x^3.088 6,y=0.005 3x^2.683 4,壳高、壳宽与壳长关系式分别为y=0.667 4x＋0.305 9,y=0.457 5x-0.967 8;1～3龄蛤仔软体部的生长速度快于贝壳,5～6月份是菲律宾蛤仔的肥育期.由个体生长特性分析,3龄为最佳采捕年龄,从生物量上分析,采捕2龄蛤收益最高;6月是最佳的捕获季节.     

斜带髭鲷幼鱼生长和生态转换效率的研究

在实验室内, 22. 5±0. 5℃条件下以去头去骨去鳞片去皮的金色小沙丁鱼的纯肉糜为饵料饲养斜带髭鲷幼鱼,测定体重范围在 4. 6~6. 5g的斜带髭鲷的体重、体长的生长曲线及其生态转换效率和特定生长率.实验结果表明,斜带髭鲷的体重、体长在实验期间直线增长,体重、体长的生长曲线分别为Wt(w.w.湿重,下同 ) =0. 391 7t 5. 766 2(R=0. 999 6)和Lt=0. 105t 6. 265(R=0. 989 9).用胃含物法测定斜带髭鲷的胃排空率、日摄食量、日生长量、生态转换效率和特定生长率.实验得到斜带髭鲷消化道的瞬时排空率Rt= 1. 23 4×10-3 (m/m) /h,日摄食量Cd= 1. 342 9g(w.w. ),生态转换效率Eg=29. 50% ±2. 77% [m/m(w.w. ) ],特定生长率SGR=4. 71%±0. 69% [m/m(w.w. ) ].     

Influence of water logging time on the growth of candel seedlings

Influence ofwaterlogging time on the growth ofKandeliacandel(L.) Druce seedlings grown for 70 d in the artificial-tidal tanks' simulated semidiumal tide under greenhouse is studied. Sand and soil act as the substrate and artificial sea-water with salinity of 15 is used in cultivation. Shorter waterlogging time (inundated for about 2 ～ 4 h) promotes thegrowth of K. candel seedlings, while longer time(inundated more than 8 h) or no waterlogging(0 h) inhibits theirgrowth. The number and length of aerating roots increase with the increase ofwaterlogging time. Under existing condi-tions, the optimalwaterlogging time for the growth of K. canoel seedlings is about 2 ～ 4 h in every tide cycle. Com-pared with other treatments, the 2 h sanded treatments obtain the highest biomass of seedlings, have the lowest massloss ofhypocotyl and broaden the photosynthetic area by increasing the area per leaf after 70-d cultivation. And the soiltreatments have the similar tendeney. However, waterlogging for 8 h in every tide cycle is critieal for normal develop-ment of seedlings. K. candel seedlings are highly tolerant to waterlogging and a proper waterlogging is beneficial to thegrowth ofK. candel seedlings.     

盐度和营养限制对蓝杆藻(Cyanothece. sp)113菌株生长和胞外多糖产量的影响

蓝杆藻113菌株为海洋微藻，实验室培养证明其单位体积胞外多糖产量高。用改进的F／2改良培养液培养，添加70g／L时的NaCl盐度是该菌株胞外多糖释放的最适盐度。不添加NaCl时的盐度是菌体细胞生长的最适盐度。NaNO2营养限制抑制该菌株细胞的生长，促进该菌株胞外多糖的释放。NaH2PO4营养限制抑制该菌株细胞的生长，但对胞外多糖产量的影响不明显。MgSO4营养限制则同时抑制该菌株细胞生长和胞外多糖释放。该研究结果有助于蓝杆藻113菌株胞外多糖的生产及该菌株其它方面的开发利用。     

适宜浓度的维生素E促进半滑舌鳎生长激素基因的表达

本实验旨在探究维生素E对半滑舌鳎垂体组织中生长激素基因表达的影响。作者在每千克等氮等能的基础饲料中分别添加0、400和1 600mg的DL-α-生育酚乙酸酯(维生素E)投喂半滑舌鳎(Cynoglossus semilaevis)成鱼(464±2.6) g,进行为期8周的养殖实验;另外,在L-15培养基中添加0、18和54μmol/L的维生素E,对半滑舌鳎成鱼(464±2.6) g的垂体细胞进行为期3 d的体外原代培养实验。分别取垂体组织和原代细胞,通过荧光实时定量PCR分析其gh mRNA的相对表达量。实验结果表明:垂体组织中gh mRNA的相对表达量随着饲料中维生素E含量的增加而呈现先升高后下降的变化趋势,在400 mg/kg组时显著高于其他各组(P0.05);随着细胞培养液中维生素E浓度的升高, gh mRNA的相对表达量显著增加(P0.05)。由此可见,适宜浓度的维生素E能够促进半滑舌鳎垂体组织中生长激素基因的表达。     

2017年春季季风间期南海中北部浮游植物生长与微型浮游动物摄食

Phytoplankton growth rates and mortality rates were experimentally examined at 21 stations during the 2017 spring intermonsoon(April to early May) in the northern and central South China Sea(SCS) using the dilution technique, with emphasis on a comparison between the northern and central SCS areas which had different environmental factors. There had been higher temperature but lower nutrients and chlorophyll a concentrations in the central SCS than those in the northern SCS. The mean rates of phytoplankton growth(μ_0) and microzooplankton grazing(m) were(0.88±0.33) d~(–1) and(0.55±0.22) d~(–1) in the central SCS, and both higher than those in the northern SCS with the values of μ_0((0.81±0.16) d~(–1)) and m((0.30±0.09) d~(–1)), respectively.Phytoplankton growth and microzooplankton grazing rates were significantly coupled in both areas. The microzooplankton grazing impact(m/μ_0) on phytoplankton was also higher in the central SCS(0.63±0.12) than that in the northern SCS(0.37±0.06). The microzooplankton abundance was significantly correlated with temperature in the surface. Temperature might more effectively promote the microzooplankton grazing rate than phytoplankton growth rate, which might contribute to higher m and m/μ_0 in the central SCS. Compared with temperature, nutrients mainly affected the growth rate of phytoplankton. In the nutrient enrichment treatment,the phytoplankton growth rate(μn) was higher than μ_0 in the central SCS, suggesting phytoplankton growth in the central SCS was nutrient limited. The ratio of μ_0/μn was significantly correlated with nutrients concentrations in the both areas, indicating the limitation of nutrients was related to the concentrations of background nutrients in the study stations.