Abstract
Industrial biotechnology, also known as biomanufacturing, is one of the most creative and labour-productive sectors of the economy. It uses biological materials to create more commercially viable goods, such as pharmaceuticals and food processing, with the expectation of stable economic growth and the creation of new value chains that are more environmentally friendly than those in the chemical industry. One of the numerous metabolically diverse genera with recently discovered features in a variety of habitats is pseudomonas. These gram-negative microbial species have shown a remarkable innate capacity to thrive in unfavourable environments and adapt to trying situations. Pseudomonas species are known as one of the effective biopolymer producers in terms of its medium-chain-length polyhydroxyalkanoates, which is growing in biomanufacturing in environmental prospects (PHAs). Pseudomonas putida are constituted of various functional and structural components, along with synthetic biology techniques that facilitate the localisation, decoding, and characterisation in biomanufacturing production. The performance and proliferation of cells are enhanced by changing optimum flux engineering in microorganisms, which lessens the negative impacts on cell metabolism.
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Kamaludin, N.H., Feisal, N.A.S. (2023). Biomanufacturing for Sustainable Production of Biomolecules: Pseudomonas putida Cell Factory. In: Singh, V., Show, P.L. (eds) Biomanufacturing for Sustainable Production of Biomolecules. Springer, Singapore. https://doi.org/10.1007/978-981-19-7911-8_9
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