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@PHDTHESIS{Okrob:20792,
author = {Okrob, Danial},
title = {{O}ptimierung der {H}ydroxynitril-{L}yase aus {A}rabidopsis
thaliana für die enantio-selektive {S}ynthese von
({R})-{C}yanhydrinen: {E}ntwicklung und {E}tablierung
geeigneter {R}eaktionsparameter und molekulare
{S}tabilisierung durch rationales {E}nzymdesign},
volume = {53},
school = {Universität Düsseldorf},
type = {Dr. (Univ.)},
address = {Jülich},
publisher = {Forschungszentrum Jülich GmbH Zenralbibliothek, Verlag},
reportid = {PreJuSER-20792},
isbn = {978-3-89336-782-5},
series = {Schriften des Forschungszentrums Jülich. Reihe Gesundheit
/ Health},
pages = {XV, 135 S.},
year = {2012},
note = {Record converted from JUWEL: 18.07.2013; Universität
Düsseldorf, Diss., 2012},
abstract = {In this work the potential of the hydroxynitrile lyase from
$\textit{Arabidopsis thaliana}$ (AtHNL) for the
enantioselective synthesis of industrially important
cyanohydrins was demonstrated by two different principles:
reaction- and protein engineering. The enantiomeric excess
of this enzymatic reaction is strongly compromised by a
non-selective side-reaction resulting in racemic
cyanohydrins and thus lowering the enantiomeric excess of
the biotransformation. This non-selective product formation
is influenced by pH, temperature and the water content of
the reaction medium. For industrial applications aqueous or
aqueous-organic reaction systems are used where the racemic
product formation is suppressed by lowering the pH below pH
5 and running the process at $\le$ 10 °C. However, both
approaches are not feasible with AtHNL, since the enzyme is
rapidly inactivated below pH 5. In order to enable the use
of AtHNL for the enantioselective synthesis of industrial
important cyanohydrins two strategies were developed in this
work. The first strategy concerned the suppression of the
racemic product formation by reaction engineering. Thereby,
a micro-aqueous reaction medium (buffer-saturated
mono-phasic methyl $\textit{tert}$. butyl ether) was used to
suppress the undesired side reaction, which resulted in a
good enzymatic activity and high enantioselectivities for
several industrially important cyanohydrins. Efficient
cyanohydrin syntheses were reached in the established
reaction system by application of whole cells and the use of
immobilized enzyme (e.g., enzyme adsorption at celite
particles, encapsulation in solgel, cross-linking of enzyme
aggregates), espectively. Best results were obtained using
whole recombinant $\textit{E. coli}$ cells as well as
celite-adsorbed isolated AtHNL. For the synthesis of (R)-
mandelonitrile both preparations showed comparable catalytic
efficiencies, process-and storage stabilities, resulting in
a maximal productivity of ~1.6 g (R)-mandelonitrile per g
wet cell mass (after 6-8 recycling steps). The second
strategy was the development of a stabilized AtHNL variant
which is stable under acidic conditions and thus applicable
in industrially established aqueous-organic two-phase
reaction systems. Based on the highly similar HNL from
$\textit{Manihot esculenta}$ (MeHNL), which is stable under
these conditions, the protein [...]},
cin = {IBT-2},
ddc = {500},
cid = {I:(DE-Juel1)VDB56},
pnm = {Biotechnologie},
pid = {G:(DE-Juel1)FUEK410},
typ = {PUB:(DE-HGF)11 / PUB:(DE-HGF)3},
url = {https://juser.fz-juelich.de/record/20792},
}
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