TY - JOUR
T1 - 300-fold increase in production of the Zn2+-dependent dechlorinase trzN in soluble form via apoenzyme stabilization
AU - Jackson, Colin J.
AU - Coppin, Christopher W.
AU - Carr, Paul D.
AU - Aleksandrov, Alexey
AU - Wilding, Matthew
AU - Sugrue, Elena
AU - Ubels, Joanna
AU - Paks, Michael
AU - Newman, Janet
AU - Peat, Thomas S.
AU - Russell, Robyn J.
AU - Field, Martin
AU - Weik, Martin
AU - Oakeshott, John G.
AU - Scott, Colin
PY - 2014
Y1 - 2014
N2 - Microbial metalloenzymes constitute a large library of biocatalysts, a number of which have already been shown to catalyze the breakdown of toxic chemicals or industrially relevant chemical transformations. However, while there is considerable interest in harnessing these catalysts for biotechnology, for many of the enzymes, their large-scale production in active, soluble form in recombinant systems is a significant barrier to their use. In this work, we demonstrate that as few as three mutations can result in a 300-fold increase in the expression of soluble TrzN, an enzyme from Arthrobacter aurescens with environmental applications that catalyzes the hydrolysis of triazine herbicides, in Escherichia coli. Using a combination of X-ray crystallography, kinetic analysis, and computational simulation, we show that the majority of the improvement in expression is due to stabilization of the apoenzyme rather than the metal ion-bound holoenzyme. This provides a structural and mechanistic explanation for the observation that many compensatory mutations can increase levels of soluble-protein production without increasing the stability of the final, active form of the enzyme. This study provides a molecular understanding of the importance of the stability of metal ion free states to the accumulation of soluble protein and shows that differences between apoenzyme and holoenzyme structures can result in mutations affecting the stability of either state differently.
AB - Microbial metalloenzymes constitute a large library of biocatalysts, a number of which have already been shown to catalyze the breakdown of toxic chemicals or industrially relevant chemical transformations. However, while there is considerable interest in harnessing these catalysts for biotechnology, for many of the enzymes, their large-scale production in active, soluble form in recombinant systems is a significant barrier to their use. In this work, we demonstrate that as few as three mutations can result in a 300-fold increase in the expression of soluble TrzN, an enzyme from Arthrobacter aurescens with environmental applications that catalyzes the hydrolysis of triazine herbicides, in Escherichia coli. Using a combination of X-ray crystallography, kinetic analysis, and computational simulation, we show that the majority of the improvement in expression is due to stabilization of the apoenzyme rather than the metal ion-bound holoenzyme. This provides a structural and mechanistic explanation for the observation that many compensatory mutations can increase levels of soluble-protein production without increasing the stability of the final, active form of the enzyme. This study provides a molecular understanding of the importance of the stability of metal ion free states to the accumulation of soluble protein and shows that differences between apoenzyme and holoenzyme structures can result in mutations affecting the stability of either state differently.
UR - http://www.scopus.com/inward/record.url?scp=84902202029&partnerID=8YFLogxK
U2 - 10.1128/AEM.00916-14
DO - 10.1128/AEM.00916-14
M3 - Article
SN - 0099-2240
VL - 80
SP - 4003
EP - 4011
JO - Applied and Environmental Microbiology
JF - Applied and Environmental Microbiology
IS - 13
ER -