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154 Part 2: Biotechnology and Enzymology
Figure 7.22.Principal scheme of using CAAX-tagged proteins for covalent modification with prenyl transferases.
ENZYME UTILISATION IN INDUSTRY
Enzymes offer potential for many exciting applications in in-
dustry. Some important industrial enzymes and their sources are
listed in Table 7.9. In addition to the industrial enzymes listed
above, a number of enzyme products have been approved for
therapeutic use. Examples include tissue plasminogen activator
and streptokinase for cardiovascular disease, adenosine deami-
nase for the rare severe combined immunodeficiency disease,β-
glucocerebrosidase for Type 1 Gaucher disease,l-asparaginase
for the treatment of acute lymphoblastic leukemia, DNAse for
the treatment of cystic fibrosis and neuraminidase which is being
targeted for the treatment of influenza (Cutler 2003).
There are also thousands of enzyme products used in small
amounts for research and development in routine laboratory
practice and others that are used in clinical laboratory assays.
This group also includes a number of DNA- and RNA-modifying
enzymes (DNA and RNA polymerase, DNA ligase, restriction
endonucleases, reverse transcriptase, etc.), which led to the de-
velopment of molecular biology methods and were a foundation
for the biotechnology industry (Yeo et al. 2004). The clever ap-
plication of one thermostable DNA polymerase led to the PCR
and this has since blossomed into numerous clinical, forensic and
academic embodiments. Along with the commercial success of
these enzyme products, other enzyme products are currently in
commercial development.
Another important field of application of enzymes is in
metabolic engineering. Metabolic engineering is a new ap-
proach involving the targeted and purposeful manipulation of
the metabolic pathways of an organism, aiming at improving
the quality and yields of commercially important compounds.
It typically involves alteration of cellular activities by manipu-
lation of the enzymatic functions of the cell using recombinant
DNA and other genetic techniques. For example, the combina-
tion of rational pathway engineering and directed evolution has
been successfully applied to optimise the pathways for the pro-
duction of isoprenoids such as carotenoids (Schmidt-Dannert
et al. 2000, Umeno and Arnold 2004).