本实验为解释盐生杜氏藻在面临高渗胁迫下快速合成甘油的机制提供了帮助。
This experiment may be helpful for the explanation of the rapid glycerol synthesis in D. salina under hyperosmola…
杜氏藻还是耐盐性最强的真核生物,是研究抗盐性生理及其分子机制的方便的模式生物。
It was the most salt tolerent eukaryote and the model organism to study the molecular mechanism of saline tolerent physiology.
他与他的团队推测这些微生物之所以可以存活一千年是由于一种属于杜氏藻的海藻,这种海藻也被困在盐中被盐包裹。
He and his team suspect that the microbes survived over the millennia thanks to an algae called Dunaliella, which also became trapped and encased in the salt.
至于该细菌为何会拥有如此惊人的寿命,他认为应该是它们终年生活在“杜氏盐藻”中的原因。
The reason for the microbes' astounding life span appears to be due to the fact that they were trapped alongside the algae of a group called Dunaliella.
目的:克隆杜氏盐藻核基质附着区(MAR)结合蛋白片段。
Aim: To clone MAR-binding protein cDNA fragment from Dunaliella salina.
结论:所克隆的序列可能为杜氏盐藻MAR结合蛋白片段。
Conclusion: The cloned sequence is probably MAR binding protein cDNA fragment from Dunaliella salina.
目的:克隆杜氏盐藻双拷贝碳酸酐酶(DCA1)和碳酸酐酶(CA1)基因跨内含子基因组dna序列。
Aim: To clone the cross-intron genomic DNAs of the duplicated carbonic anhydrase (DCA1) and carbonic anhydrase (CA1) genes from Dunaliella salina.
本文系统研究了杜氏盐藻的生物学特性,主要内容包括杜氏盐藻无菌纯化、杜氏盐藻生理学特性、杜氏盐藻遗传学特性等三部分。
In this thesis, the biological characteristic of Dunaliella salina, which included the axenic purification, physiology characteristics and genetics characteristics, was studied systematically.
本文系统研究了杜氏盐藻的生物学特性,主要内容包括杜氏盐藻无菌纯化、杜氏盐藻生理学特性、杜氏盐藻遗传学特性等三部分。
In this thesis, the biological characteristic of Dunaliella salina, which included the axenic purification, physiology characteristics and genetics characteristics, was studied systematically.
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