Next‐Generation Industrial Biotechnology‐Transforming the Current Industrial Biotechnology into Competitive Processes

The chemical industry has made a contribution to modern society by providing cost‐competitive products for our daily use. However, it now faces a serious challenge regarding environmental pollutions and greenhouse gas emission. With the rapid development of molecular biology, biochemistry, and synth...

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Published in:Biotechnology journal 2019-09, Vol.14 (9), p.e1800437-n/a
Main Authors: Yu, Lin‐Ping, Wu, Fu‐Qing, Chen, Guo‐Qiang
Format: Article
Language:English
Subjects:
Biotechnology - methods
extremophilic microorganisms
Fermentation - physiology
Halomonas
Halomonas - metabolism
industrial biotechnology
next‐generation industrial biotechnology
open continuous fermentation
polyhydroxyalkanoates
Polyhydroxyalkanoates - metabolism
Synthetic Biology - methods
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creator Yu, Lin‐Ping
Wu, Fu‐Qing
Chen, Guo‐Qiang
description The chemical industry has made a contribution to modern society by providing cost‐competitive products for our daily use. However, it now faces a serious challenge regarding environmental pollutions and greenhouse gas emission. With the rapid development of molecular biology, biochemistry, and synthetic biology, industrial biotechnology has evolved to become more efficient for production of chemicals and materials. However, in contrast to chemical industries, current industrial biotechnology (CIB) is still not competitive for production of chemicals, materials, and biofuels due to their low efficiency and complicated sterilization processes as well as high‐energy consumption. It must be further developed into “next‐generation industrial biotechnology” (NGIB), which is low‐cost mixed substrates based on less freshwater consumption, energy‐saving, and long‐lasting open continuous intelligent processing, overcoming the shortcomings of CIB and transforming the CIB into competitive processes. Contamination‐resistant microorganism as chassis is the key to a successful NGIB, which requires resistance to microbial or phage contaminations, and available tools and methods for metabolic or synthetic biology engineering. This review proposes a list of contamination‐resistant bacteria and takes Halomonas spp. as an example for the production of a variety of products, including polyhydroxyalkanoates under open‐ and continuous‐processing conditions proposed for NGIB. The concept of next‐generation industrial biotechnology (NGIB) can be defined as low‐cost mixed substrates based on less freshwater consumption, energy‐saving, and long‐lasting open and continuous intelligent processing.
doi_str_mv 10.1002/biot.201800437
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Contamination‐resistant microorganism as chassis is the key to a successful NGIB, which requires resistance to microbial or phage contaminations, and available tools and methods for metabolic or synthetic biology engineering. This review proposes a list of contamination‐resistant bacteria and takes Halomonas spp. as an example for the production of a variety of products, including polyhydroxyalkanoates under open‐ and continuous‐processing conditions proposed for NGIB. 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subjects Biotechnology - methods
extremophilic microorganisms
Fermentation - physiology
Halomonas
Halomonas - metabolism
industrial biotechnology
next‐generation industrial biotechnology
open continuous fermentation
polyhydroxyalkanoates
Polyhydroxyalkanoates - metabolism
Synthetic Biology - methods
title Next‐Generation Industrial Biotechnology‐Transforming the Current Industrial Biotechnology into Competitive Processes
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