Structure of an aliphatic amidase from Geobacillus pallidus RAPc8
View/ Open
Date
2007Author
Kimani, Serah W.
Agarkar, Vinod B.
Cowan, Donald A.
Sayed, Muhammed F.
Sewell, B. Trevor
Metadata
Show full item recordAbstract
The amidase from Geobacillus pallidus RAPc8, a moderate
thermophile, is a member of the nitrilase superfamily and
catalyzes the conversion of amides to the corresponding
carboxylic acids and ammonia. It shows both amide-hydrolysis
and acyl-transfer activities and also exhibits stereoselectivity
for some enantiomeric substrates, thus making it a potentially
important industrial catalyst. The crystal structure of
G. pallidus RAPc8 amidase at a resolution of 1.9 A ˚ was
solved by molecular replacement from a crystal belonging to
the primitive cubic space group P4232. G. pallidus RAPc8
amidase is homohexameric in solution and its monomers have
the typical nitrilase-superfamily α-β-β-α fold. Association in
the hexamer preserves the eight-layered α-β-β-α:α-β-β-α
structure across an interface which is conserved in the known
members of the superfamily. The extended carboxy-terminal
tail contributes to this conserved interface by interlocking the
monomers. Analysis of the small active site of the G. pallidus
RAPc8 amidase suggests that access of a water molecule to the
catalytic triad (Cys, Glu, Lys) side chains would be impeded by
the formation of the acyl intermediate. It is proposed that
another active-site residue, Glu142, the position of which is
conserved in the homologues, acts as a general base to catalyse
the hydrolysis of this intermediate. The small size of the
substrate-binding pocket also explains the specificity of this
enzyme for short aliphatic amides and its asymmetry explains
its enantioselectivity.