The Possible Role of Molecular Vibration in Intracellular Signalling

" The Golgi apparatus and the microtubule skeleton system are the decisive structures for numerous intracellular transport tasks . Close communication between the Golgi apparatus and the cell periphery is an absolute prerequisite for the well-directed positioning of structural elements. The majority of the substances that influence the cell from the membrane transmit the information to the intracellular destination via signal transduction pathways. It is discussed in detail that the transmission of information in both systems is based on emission and resonance of electromagnetic patterns in the infrared frequency range generated by the vibrations of the respective molecules. This radiation with fingerprint patterns must be coherent to activate enzymes. Coherence could be achieved by the chemical reactions of the molecules to be replaced or in the signal transduction pathways, by the phosphorylation of the transduction proteins. The quasicrystalline structure of water is essential for that coherence." {Credits 1}

" Corresponding to our hypothesis that intracellular signalling processes are mainly carried out by photons, it can be assumed that the communication between these chain links takes place using electromagnetic fields which transfer the particular information and leads to the specific enzyme activation. The signals that pass through the intracellular transduction pathway are extremely diverse leading to different effects. Because a large variety of different receptor proteins exists in the cell membrane the primary messengers can find suitable receptors. In contrast to the large variety of receptors, the variety of proteins in the transduction cascades is limited. Different signals have been conducted through the same cascades. In principle, a protein can resonate different frequency patterns resulting in different conformational changes. The emitted vibration pattern would mirror that. A protein of the transduction cascade can, therefore, receive and transmit different signals." {Credits 1}

{Credits 1} 🎪 Jaross W. The Possible Role of Molecular Vibration in Intracellular Signalling. J Cell Signal 2020; 1(4): 180-186. © 2020 Jaross W. This open access article is distributed under Creative Commons Attribution License.

Last modified on 06-Dec-20

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