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Originally posted by johncarter
reply to post by Manunnaki
You forgot to add Hertz after your brave claim (7.83), that btw lacks any scientific credibility and belong more in the new age section of ATS than on this S&T thread .edit on 12-2-2013 by johncarter because: (no reason given)
DNA sequence itself could be reconstituted from the electromagnetic signal.
The filtrate (solution that went through the filter) was sterile, and no bacterium grew in a rich culture medium that would normally support its growth. Furthermore, polymerase chain reactions (PCR) based on primers (short starting sequences) derived from adhesin, a gene of the bacterium that had been cloned and sequenced, failed to detect any DNA in the filtrate. But, to Montagnier’s surprise, when the filtrate was incubated with lymphocytes that were not infected with Mycoplasm (according to the most stringent tests), the bacterium was regularly recovered. So, was there some information in the filtrate responsible for directing the synthesis of the bacterium? That marked the beginning of a long series of investigations on how DNA behaves in water, which led to the discovery that the M. pirum DNA was emitting low frequency electromagnetic waves in some diluted solutions of the filtrate in water, and this property of M. pirum DNA was soon extended to other bacterial and viral DNA [1, 2]. The instrument used to detect the electromagnetic (EM) signals consists of a solenoid (a coil of wire) that detects the magnetic component of the waves produced by the DNA solution in a plastic tube as it induces an electric current in the wire. This current is amplified and analysed in a laptop computer using special software, and the resultant signals plotted out on the computer screen.
This suggests an explanation for Montagnier’s original observation made ten years ago that the bacterium could be reconstituted from a sterile filtrate incubated with human lymphocytes. The EM signals of all the bacterium’s DNA were in the sterile filtrate. The nanostructures induced by M. pirum DNA in the filtrate carried information representing different segments of its genomic DNA. Each nanostructure, when in contact with the human lymphocytes, directs the synthesis of the corresponding DNA by the DNA polymerases in the cell. There is then a certain probability that each piece of DNA recombines within the cell to reconstruct the whole DNA genome of Mycoplasm. From there, the synthesis of the rest of the bacterium – membrane lipids, ribosomes, and proteins – could take place, thanks to the host cells. One single reconstituted Mycoplasm is sufficient to infect the lymphocytes. “All the steps assumed in the regeneration from water can be analysed and open to verification.” The researchers wrote .