Businesses which specialize in developing, deploying, or supporting a multiuser computer system. An IT director usually oversees a team of sys admins responsible for configuring, maintaining and supporting technology tools within an organization.
Simulations demonstrate that patterns of gene spread under both stochastic and deterministic processes are generally similar, with traveling waves of advantageous genes fluctuating when recombination rates change (SI Figs. 1a-c).
Waves of Advance
Ants provide an apt analogy for understanding evolutionary dynamics. A population of ants will typically show alternative genetic variants increasing gradually until becoming dominant or even disappearing altogether, depending on initial conditions and local spread rates; but overall this creates an obvious wave-like dynamics that can be observed over time.
Traditional genetics views DNA as an organic machine; wave genetics takes an entirely different view, viewing DNA as an intelligent system able to communicate and exchange information with space through electromagnetic and acoustic waves. Proponents have even created technology allowing direct contact between their cells’ DNA and specific frequencies that enable direct regeneration, healing and longevity increases.
Researchers have also applied this theory to linguistics, using it to study Creole languages and mixed dialects such as English. Furthermore, their results demonstrated how adenine, guanine, cytosine, thymine and oxygen interact through sound frequencies during speech; their interactions forming DNA fingerprints of their organism over time.
Pavel Gariaev from Russia was one of the pioneers of wave genetics. In multiple experiments that confirmed his theory, he used a special frequency to communicate with individual DNA and regenerate an injured pancreas – all without employing risky technologies like recombinant DNA or stem cells.
He discovered that DNA video tapes, which contain instructions for maintaining health and vitality in organisms, become corrupted over time due to DNA mutations; as a result of which an organism gets sick, dies, ages or goes dormant. But these corrupted videos can be renewed or restored for optimal healing, longer lifespan and greater consciousness.
Wave genetics suggests that DNA-wave interactions play an integral part in shaping species diversity, demographic history and population structure. Furthermore, Wave genetics has been used to explain “DNA Phantom Effects.” This refers to when an animal or person first sexually encounters one male before having sexual relations with other men, some offspring may still contain genetic features from that original male that will remain unchanged by subsequent sexual relationships with different men.
Waves of Diffusion
Montagnier and his colleagues conducted experiments to study the impact of DNA waves on bacterial replication by irradiating dilute aqueous solutions containing bacteria with electromagnetic waves, producing low-frequency electromagnetic signals emitted by DNAs that caused changes to electrical charges and electrons that led to changes in topology of DNA molecules.
The topology of DNA dictates how it coils, winds and packs itself into chromosomes. Different topologies produce differently-shaped chromosomes with distinct waves – these waves may even impact gene expression or cell division.
Some waves act like enzymes to unravel DNA for reading; others interact directly with its structure to alter its topology and cause double-helix regions to detach or unwind, opening new regions up for mutation.
Researchers also studied how DNA waves generated by bacteria varied with temperature. At lower temperatures, less DNA waves were generated; additionally, current value of particular waves could identify whether bacteria was male or female due to differences between males and females in topological DNAs in cells of each gender.
Waves of Recombination
The Wave Theory of Gene Spread proposes that mating systems may either impede or promote the spread of advantageous genes depending on how the system interacts with selection and gene flow. Gene spreading patterns are dictated by population density and gene flow rates; high selfing rates reduce gene movement between populations, decreasing the likelihood of individuals carrying beneficial alleles in each. Genetic hitchhiking – in which neutral alleles acquire and pass on favorable alleles from another population – occurs more slowly with this strategy. Gene flow depends on distance between populations as well as frequency of beneficial alleles; physical barriers may help delay their spread by restricting migration flows.
Modeling the effects of mating systems on gene spread can be accomplished using a straightforward model. When only gametic selection and no seed flow occur (sh = 0, sd = 0), gene frequency travels in waves with one unimodal distribution with maximum value near pB, reinforced by selfing; when beneficial allele spread slows, average travel times increase along with selfing rates and maximum standard deviation decreases over time.
Gene flow alters the traveling waves’ shape more dramatically; MC simulations demonstrate this via drift effects shaping an average travelling wave and that beneficial allele spread decreases with selfing rate (SI Fig 3a).
Furthermore, the pattern of traveling waves can be modified by altering population density or gene flow rates. At higher population densities, average gene travel times tend to be faster while standard deviation is reduced; at lower densities however, genetic drift effects become stronger leading to slower gene advance rates as indicated in Figure 7 below which shows average gene advance rate as a function of population density and allele frequency pB under both drift and deterministic processes.
Waves of Selfing
Wave patterns within eukaryotic cells have attracted considerable interest due to their importance in cell migration, division and nutrition uptake (Vicker et al. 1997; Vicker 2002a). Furthermore, recent live cell fluorescence microscopy studies have provided direct evidence of their dynamic formation in Xenopus laevis oocytes and Dictyostelium discoideum cells (Gerisch et al. 2004; Bretschneider et al. 2005).
A double DNA-like helix’s behavior when exposed to an electromagnetic wave with left-hand circular polarization may be summarized as follows.
If an incident electric vector makes a right turn relative to the helix axis, currents generated in two helical strands located opposite each other have opposite signs; therefore, the helix becomes practically transparent to a circularly polarized incident field and may be considered an “orthogonal vibrator.” Figure 3 displays how real parts of electric currents in these helical strands depend upon frequency proportional to wavelength of incident wave.
