绿球

In winter, the distribution of Pro was limited mainly within the Kuroshio current area, most probably by temperature.

原绿球藻在东海的分布除受水流、水团的作用外，在冬季还受温度的限制。

Biological interactions, trace metal, and chemical and physical conditions of the water column might all be the potential factors limiting the distribution of Pro to the coastal area.

实验表明，种间相互作用，微量金属元素，以及水体的物理化学条件等都是制约原绿球藻近岸分布的因素。

There are decreases in fluorescence signals except the stablility for Prochlorococcus and increasing abruptly for picoeukaryotes in phycoerythrin fluorescence.

除原绿球藻的藻红素荧光基本不变、微微型真核浮游植物的藻红素荧光大幅增加外，其余荧光信号均发生不同程度的减少。

There are decreases in fluorescence signals except the stabllllty for Prochlorococcus and increasing abruptly for pieoeukaryotes in phycoerythrin fluorescence.

除原绿球藻的藻红素荧光基本不变、微微型真核浮游植物的藻红素荧光大幅增加外，其余荧光信号均发生不同程度的减少。

Compared with the cell cultured in BG11, the cell wall of the cells cultured at low concentration of Cu2+(0.01～1 mg/L) did not markedly become thick and the chlorophyll did not change notably, but the number of pyrenoid increased.

结果表明，Cu2+对绿球藻的显微结构﹑生长及生理状态的影响比较显著。

However, the cell wall cultured at high concentration of Cu2+(10～200 mg/L) was clearly thickened and became multiple layers, and the pigment decreased and the pyrenoid became one or disappeared. Low concentration of Cu2+(0.01 mg/L, 0.1 mg/L) did not affect the growth of Chlorococcum sp., but the growth became slow and even negative beyond the concentration of 0.1 mg/L.

与对照BG11培养的绿球藻比较，0.01～1 mg/L Cu2+浓度下培养的绿球藻，细胞壁无明显增厚，色素没有多大变化，但蛋白核由一个变为多个；而在高浓度(10～200 mg/L Cu2+)下，细胞壁明显增厚为多层，色素减少，蛋白核减少并回复到1个或消失。

Type genus of Chlorococcales; unicellular green algae occurring singly or in a layer on soil or damp rock.

绿球藻科的一个模式属；单细胞绿色海藻生长在土壤或湿岩石上，独生或群生。

The removal rate of Cu2+ by Chlorococcum sp. was the largest at the concentration of 1 mg/L and reached 90.5%.

低浓度Cu2+(0.01，0.1 mg/L)对绿球藻生长无影响；高于0.1 mg/L浓度时，绿球藻生长变得缓慢甚至出现负生长。

Nutrient enrichment experiments in the South China Sea suggested that, Syn and Euk were similar in characteristics of high demanding for Fe and N.

南海营养盐添加实验表明，原绿球藻似乎更受磷限制，而聚球藻和超微型真核生物对铵氮的添加反应更明显。

In 75m in the South China Sea, Fe enriched from a large range of concentrations stimulated the growth of nanoplankton. For the picoplankton, Fe enrichment of nano-molar level increased the cell abundance of Euk, on the other hnad, Syn and Pro had significant responses to higher concentration of Fe enrichment.

75米层海水铁添加实验表明，不同浓度的铁均促进nano-级的浮游植物的生长；对于超微型浮游植物来说，纳摩尔级铁的添加有利于超微型真核生物的生长，而更高浓度的铁添加则对聚球藻和原绿球藻的生长有利。

chlorella：綠球藻

绿球藻(Chlorella)的发现人类使用微藻类历史最早可追溯自史前时代的狩猎民族,他们常采集土壤中的一种胶状性蓝绿藻(Nostoc Commune)食用,而有计划地大量培养微藻则始于第一次世界大战期间,德国哥庭根大学林纳德教授,

yellow spot：黄球置点

置球点 spots | 黄球置点 yellow spot | 绿球置点 green spot

Chlorococcaceae：绿球藻科

卵囊藻科Oocystaceae | 绿球藻科Chlorococcaceae | 网球藻科Dictyosphaeraceae

Chlorococcales：绿球藻目

湖泊中最常见的浮游性绿藻为属於团藻目(Volvocales)、绿球藻目(Chlorococcales)和鼓藻目(Desmidiales)的种类. 团藻目的细胞都具有鞭毛,喜欢生长於富营养性水域,例如实球藻属(Pandorina, 图七);绿球藻目的营养细胞都不具鞭毛,

Chlorococcales：(三)绿球藻目

(二)四孢藻目Tetrasporales | (三)绿球藻目Chlorococcales | (四)丝藻目Ulotrichales

Chlorococcales：(三)绿球藻日

5.胶球藻科Coccomyxaceae | (三)绿球藻日Chlorococcales | 1.绿球藻科Chlorococcaceae

Chlorococcum：绿球藻(属)

綠杞(四川) Cornus chinenisis Wagner | 綠球藻屬 Chlorococcum | 綠色鞭毛藻科 Chloromonadaceae

Chlorococcum：绿球藻

拟新月藻 Closteriopsis | 绿球藻 Chlorococcum | 浮球藻 Plantosphaeria

Chlorococcum Meneghini：绿球藻属

1.绿球藻属Chlorococcum Meneghini | 2.共球藻属Trebouxia de Puymaly | 3.绿点藻属Chlorochytrium Cohn

zoochlorella：动物共生绿球藻

带口粒(花粉) zonorate grain | 动物共生绿球藻 Zoochlorella | 动物分布 zoochory