The latterone is useful for the bio

The latter
one is useful for the biotechnological production of 2-oxoadipate,
a precursor of adipic acid. 2-Oxoadipate could be converted to
adipic acid either by chemo-catalytic reduction or enzymatically
in engineered cells (see below). In S. cerevisiae the -aminoadipate
pathway consists of 8 enzymatic reactions to yield l-lysine from 2-
oxoglutarate and acetyl-CoA. The first three enzymatic steps yield
2-oxoadipate (Fig. 6). The first reaction, catalyzed by homocitrate
synthase, is the condensation of 2-oxoglutarate and acetyl-CoA
to yield homocitrate and CoA. Homocitrate synthase usually is
feedback-inhibited by l-lysine which modulates the metabolic
flux through the -aminoadipate pathway (Luengo et al., 1980;
Maragoudakis et al., 1967; Wulandari et al., 2002). Depending
on internal l-lysine levels in recombinant producer strains, the
feedback inhibition could be a limiting factor for the production
of 2-oxoadipate via the -aminoadipate pathway. Recently, the
structural basis for l-lysine feedback inhibition of homocitrate synthase
from Thermus thermophilus and S. cerevisiae was elucidated
(Bulfer et al., 2010; Okada et al., 2009). Substitutions of decisive
amino acid residues were identified which resulted in l-lysineinsensitive
variants of homocitrate synthase. This information
is important when considering the production of 2-oxoadipate
via homocitrate. Alternatively, 2-oxoadipate could be produced
using the degradation route of the amino acid l-lysine via the
intermediates saccharopine, 2-aminoadipate 6-semialdehyde, and
2-aminoadipate (KEGG map00310). For animal feed more than
1,400,000 tons/y of l-lysine are already produced by fermentation
processes using high-performance strains of Corynebacterium glutamicum
and E. coli from sugar sources such as molasses, sucrose, or
glucose (Ajinomoto, 2011; Eggeling and Bott, 2005; Leuchtenberger
et al., 2005; Wendisch et al., 2006).