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Chapter 4 - Genome management and analysis: prokaryotes
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- By Colin R. Harwood, University of Newcastle, UK, Anil Wipat, University of Newcastle, UK
- Edited by Colin Ratledge, University of Hull, Bjorn Kristiansen
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- Book:
- Basic Biotechnology
- Published online:
- 05 June 2012
- Print publication:
- 25 May 2006, pp 73-118
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- Chapter
- Export citation
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Summary
Introduction
Gene manipulation is a core technology used for a wide variety of academic and industrial applications. In addition to representing an extremely powerful analytical tool, it can be used to: (i) increase the yield and quality of existing products (e.g. proteins, metabolites or even whole cells); (ii) improve the characteristics of existing products (e.g. via protein engineering); (iii) produce existing products by new routes (e.g. pathway engineering); and (iv) develop novel products not previously found in nature (e.g. directed or hybrid biosynthesis). This chapter assumes knowledge of the basic structure and properties of nucleic acids, the organisation of the genetic information into genes and operons, and the mechanisms by which bacteria transcribe and translate this encoded information to synthesise proteins (see also Chapter 2).
Bacterial chromosomes and natural gene transfer
Bacterial chromosomes
Chromosomes are the principal repositories of the genetic information, the site of gene expression and the vehicle of inheritance. The term chromosome, meaning dark-staining body, was originally applied to the structures visualised in eukaryotic organisms by light microscopy. The use of this term has now been extended to describe the physical structures that encode the genetic (hereditary) information in all organisms. The term genome is used in the more abstract sense to refer to the sum total of the genetic information of an organism. The term nucleoid is applied to a physical entity that can be isolated from a bacterial cell and that contains the chromosome in association with other components including RNA and protein.