DNA double helix structure
- 网络DNA双螺旋结构
DNA double helix structure-
DNA double helix structure
脱氧核糖核酸双螺旋结构
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The discovery of the model of DNA double helix structure was considered to be a20th century life Sciences greatest achievements .
DNA双螺旋结构模型的发现是20世纪生命科学最伟大的成就。
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We should see the nucleic acids research before the discovery of DNA double helix structure should be regarded as a whole compare with the research after it .
我们应该看到,相比双螺旋发现之后,其发现之前的核酸研究更应被视为一个有机整体。
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Just like does not have the DNA double helix structure discovery , has not inherited the transmission transmission the central dogma , also does not have today 's molecular biology .
正如没有DNA双螺旋结构的发现,就没有遗传传达传递的中心法则,也就没有今天的分子生物学。
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The first three positions were filled by medical inventions or discoveries , the X-ray machine being followed by the discoveries of penicillin and the DNA double helix structure .
排在榜单三甲位置的发明都是医学领域的重大发明或发现。紧随X光机之后的是盘尼西林(青霉素)的发明,以及DNA双螺旋结构的发现。
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Avoiding the intense competition in the discovery of DNA double helix structure which is studied frequently , we choose the cooperation between competitors which is rarely concerned as research subject .
避开被频繁研究的发现DNA双螺旋过程中的激烈竞争,选择极少被提及的竞争对手之间的合作作为研究对象,通过大量可靠的史料分析论证竞争中的合作在双螺旋探寻路上发挥的作用。
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Base on the analysis and demonstration of the role of cooperation in the competition in the search for DNA double helix structure , we discuss the relationship between competition and cooperation in science discovery . 4 .
在上述前提下,简要讨论科学发现中竞争与合作的关系。
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To philosophical think for between relationship of The theory of warpage of space time of Einstein and biological DNA double helix structure . It is possible a principle of movement of warpage of space time for the order of control the life time of coding biology clock gene .
对爱因斯坦的弯曲时空理论与生物体DNA双螺旋结构的相关性进行了哲理性思考:控制生命时间程序的生物钟基因编码在DNA双螺旋结构上可能具有时空弯曲的运动原理。
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DNA double helix , secondary structure of RNA , and elements of protein folding ;
DNA双螺旋线,RNA(译注:核糖核酸,下同)的二级结构和蛋白质折叠基元;
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Inherited global search capability , DNA genetic algorithm simulates double helix structure and utilizes molecular satisfying the Waston-Crick complementary condition to enhance the validity and the speed of convergence of the genetic algorithm . So DNA genetic algorithm can solve NP-hard problem of Flow Shop scheduling efficiently .
DNA遗传算法继承了遗传算法全局搜索的能力,同时利用DNA双螺旋结构和碱基互补配对原则进行编码运算,提高了算法的有效性和收敛速度,从而很好地解决了NP-hard性质的Flow-Shop调度问题。