Genetic modification polymerization

Abstract This chapter describes the production of cis-3,5-cyclohexadiene-l,2-diol (DHCD) from aromatic compounds, their polymerization into poly(p-phenyelene) (or PPP), and the properties and applications of the polymer. Large-scale synthesis of DHCD has been demonstrated, and DHCD is widely used in the pharmaceutical industry, as well as in chemical industries for polymer productions. Recent study including different types of dioxygenases, strain development by recombination, and genetical modification were done to develop the process technology for commercialization of this new polymer and chemical intermediates. 

Protein synthesis is an extraordinarily complex process in which genetic information encoded in the nucleic acids is translated into the 20 amino acid alphabet of polypeptides. In addition to translation (the mechanism by which a nucleotide base sequence directs the polymerization of amino acids), protein synthesis can also be considered to include the processes of posttranslational modification and targeting. Posttranslational modification consists of chemical alterations cells use to prepare polypeptides for their functional roles. Several modifications assist in targeting, which directs newly synthesized molecules to a specific intracellular or extracellular location. 

Although chemical techniques can be used to modify the properties of biopolymers in order to expand their range of applications, this is not the unique way to improve biopolymer performance. There are different methods to transform biopolymers in sources of structural polymers that may supplant traditional commodity plastics, such as genetic manipulation of some plant species, polymerization of biological starting materials, or the creation of new gene sequences that can lead to novel protein polymers through the application of recombinant DNA methods. However, only biopolymer physical/chemical modifications will be discussed in this chapter. 

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