The Magnetic Action Phenomenon is Responsible to the Processes of DNA Replication and the Shortening of the Telomere

The chapter discusses about Magnetic Properties Govern the Processes of DNA Replication and the Shortening of the Telomere. Deoxyribonucleic acid (DNA) is the carrier of genetic information in living systems. Magnetic properties of pristine DNA and DNA-metal complexes have been intensively investigated in biological contexts The hypothesis shows that the induction and the remanent of magnetic properties govern the mechanism processes of DNA replication and the shortening of the telomere. Each parental DNA strand has a solenoid-like configuration that forms at the beginning of the replication process. This formation allows an electric charge transformation via the strand to create a magnetic field. A remanent magnetization caused by the magnetic field causes the surrounding medium to produce a new (replicated) strand. Through this magnetization process, the replicated strand possesses a similar information pattern to that of the parental strand.

Also, in this process, the remanent amount of magnetization forms the medium in which it has less of both repetitive and pattern magnetization than the parental strand. Then, the replicated strand shows a shortening in the number of the base pairs of the telomere.

A magnetic field of the whole structure of the DNA molecule encounters difficulty to be detected, although some measurements have shown no net magnetic field. As the action of this formation is to prevent the, (whole), DNA molecule from the acting in replication. Where, in this case, the two strands are been prevented to be in continuously performed in replicated action in every time in the nuclear. Then both, the spliced and unfold of the strands are important to the DNA and to its replication.