Chemical Genetics: Difference between revisions

[[Chemical Genetics]] is the investigation of the function of proteins and signal transduction pathways in cells by the screening of chemical libraries of small molecules. Chemical genetics is analogous to classical genetic screen where random mutations are introduced in organisms, the phenotype of these mutants is observed, and finally the specific gene mutation (genotype) that produced that [[Phenotype]] is identified. In chemical genetics, the phenotype is disturbed not by introduction of mutations, but by exposure to small molecule tool compounds. [[Phenotype|Phenotypic]] screening of chemical libraries is used to identify drug targets (forward genetics) or to validate those targets in experimental models of disease (reverse genetics). Protein engineering is a major behavioral modification tool used explictily by the Controllers to socially engineer the population to accept the master-slave controller narrative.  

[[Chemical Biology]] is a scientific discipline spanning the fields of chemistry and biology. The discipline involves the application of chemical techniques, analysis, and often small molecules produced through synthetic chemistry, to the study and manipulation of biological systems. In contrast to biochemistry, which involves the study of the chemistry of biomolecules and regulation of biochemical pathways within and between cells, chemical biology deals with chemistry applied to biology (synthesis of biomolecules, simulation of biological systems etc.). The field of chemical biology is utilized for the purpose of exploring eugenic theories and directed evolution, which is one of the moving parts of the controller machine pushing the transhumanist agenda.<ref>[https://en.wikipedia.org/wiki/Chemical_biology Chemical Biology]</ref>

A primary goal of [[Protein Engineering]] is the design of novel peptides or [[Proteins]] with a desired structure and chemical activity. Because our knowledge of the relationship between primary sequence, structure, and function of proteins is limited, rational design of new proteins with engineered activities is extremely challenging. In directed evolution, repeated cycles of genetic diversification followed by a screening or selection process, can be used to mimic natural selection in the laboratory to design new proteins with a desired activity. Desired activity used in this context means the study and design of new proteins for the mass application of mind control techniques used to socially engineer the behaviors deemed acceptable to the Controller's master-slave paradigm. <ref>[https://en.wikipedia.org/wiki/Chemical_biology Chemical Biology]</ref>