磁性控制DNA复制和端粒缩短的过程

World Academy of Science, Engineering and Technology, International Journal of Biological, Biomolecular, Agricultural, Food and Biotechnological Engineering Pub Date : 2013-07-22 DOI:10.19080/CTBEB.2017.08.555745

A. Y. Rojeab

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引用次数: 3

摘要

这一假设表明，磁性的诱导和残余控制着DNA复制和端粒缩短的机制过程。每条亲本DNA链的螺线管状形成，存在于复制过程的初始阶段，使电荷通过链转化产生磁场。磁场反过来又通过剩余磁化诱导周围介质形成新的(复制的)链。通过剩余磁化过程，复制链具有与亲本链相似的信息模式。在同样的过程中，剩余的磁化量形成了介质，其中它比亲本链具有更少的重复磁化和模式磁化，因此复制链的端粒长度缩短。

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Magnetic Properties Govern the Processes of DNA Replication and the Shortening of the Telomere

This hypothesis shows that the induction and the remanent of magnetic properties govern the mechanism processes of DNA replication and the shortening of the telomere. The solenoid-like formation of each parental DNA strand, which exists at the initial stage of the replication process, enables an electric charge transformation through the strand to produce a magnetic field. The magnetic field, in turn, induces the surrounding medium to form a new (replicated) strand by a remanent magnetisation. Through the remanent [residual] magnetisation process, the replicated strand possesses a similar information pattern to that of the parental strand. In the same process, the remanent amount of magnetisation forms the medium in which it has less of both repetitive and pattern magnetisation than that of the parental strand, therefore the replicated strand shows a shortening in the length of its telomeres.

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来源期刊

World Academy of Science, Engineering and Technology, International Journal of Biological, Biomolecular, Agricultural, Food and Biotechnological Engineering

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