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相关概念视频

Single-Strand DNA Binding Proteins01:03

Single-Strand DNA Binding Proteins

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For successful DNA replication, the unwinding of double-stranded DNA must be accompanied by stabilization and protection of the separated single strands of the DNA. This crucial task is performed by single-strand DNA-binding (SSB) proteins. They bind to the DNA in a sequence-independent manner, which means that the nitrogenous bases of the DNA need not be present in a specific order for binding of SSB proteins to it. The binding of SSB proteins straightens single-stranded DNA (ssDNA) and makes...
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DNA unwinding helicase enzymes are a type of motor protein. Motor proteins can translocate along filaments or polymers using energy generated from ATP hydrolysis. Helicases are involved in all the important cellular processes where DNA unwinding is required, such as DNA replication, repair, recombination, and transcription. They are present in all living organisms, but vary in their structure, function, and mechanism of action. For example, in prokaryotes, DnaB helicase binds and translocates...
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An organism’s genome needs to be duplicated in an efficient and error-free manner for its growth and survival. The replication fork is a Y-shaped active region where two strands of DNA are separated and replicated continuously. The coupling of DNA unzipping and complementary strand synthesis is a characteristic feature of a replication fork.   Organisms with small circular DNA, such as E. coli, often have a single origin of replication; therefore, they have only two replication...
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Deoxyribonucleic acid, or DNA, is the genetic material responsible for passing traits from generation to generation in all organisms and most viruses. DNA is composed of two strands of nucleotides that wind around each other to form a spring-like structure called a double helix. However, the double helix is not perfectly symmetrical. Instead, there are regularly occurring grooves in the structure. The major groove occurs where the sugar-phosphate backbones are relatively far apart. This space...
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通过DNA复合体进行螺旋依赖旋转过

Theodore J Zwang1, Sylvia Hürlimann1, Michael G Hill2

  • 1Division of Chemistry and Chemical Engineering, California Institute of Technology , Pasadena, California 91125, United States.

Journal of the American Chemical Society
|December 10, 2016
PubMed
概括
此摘要是机器生成的。

电子以自旋选择的方式穿过DNA,而DNA的结构就像一个开关. 改变DNA的手性会改变哪个电子自旋更有效地移动,从而揭示了自旋运输的洞察力.

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科学领域:

  • 分子生物物理学
  • 机器人
  • 纳米技术

背景情况:

  • 新兴的研究表明,通过像DNA这样的奇拉分子选择性电子运输.
  • 在DNA中驱动这种自旋选择性的基本机制仍然在很大程度上未被探索.
  • 了解DNA中的旋转传输对于开发新型旋转器件至关重要.

研究的目的:

  • 通过水合双重DNA研究电子传输中的自旋选择性.
  • 探索DNA螺旋性和电荷传输在自旋依赖电子迁移中的作用.
  • 为了确定DNA的超分子组织是否会影响自旋选择性.

主要方法:

  • 使用磁化DNA改性电极进行电子传输的实验.
  • 通过水合双重DNA分析自旋选择性电子传输结果.
  • 右手B-DNA和左手Z-DNA形状中的旋转选择性比较.

主要成果:

  • 通过双重DNA证明了两个电子旋转的差异迁移产量.
  • 证实了自旋选择性取决于DNA复合体内发生的电荷传输.
  • 在B和Z形式之间转换DNA时观察到类似二极管的旋转选择性,与DNA螺旋性直接相关.

结论:

  • DNA的螺旋性,特别是它的超分子组织,决定了电子运输中的自旋选择性.
  • 在DNA中的形态变化可以动态地切换特定电子旋转的首选路径.
  • 在DNA中,旋转选择性是由整体结构决定的,而不仅仅是单个单体的性.