Enhanced stereoselectivity in pig liver esterase catalysed diester hydrolysis. The role of a competitive nucleophile.

The enantioselectivity of pig liver esterase catalysed hydrolysis of cis-N-benzyl-2,5-bis(methoxy-carbonyl)pyrrolidine (1) has previously been shown to be very dependent on the reaction conditions. Hydrolysis performed in media buffered with tris(hydroxymethyl)aminomethane (Tris) afforded a monoester with much higher optical purity than hydrolysis in media without Tris. Detailed product studies in a Tris-buffered medium have been performed using NMR-techniques and a 13C-labelled ester. The NMR-studies revealed the presence of (2S,5R)-N-benzyl-2-methoxycarbonyl-5-[[[2-hydroxy-1,1- bis(hydroxymethyl)ethyl]amino]carbonyl]pyrrolidine (4) as an intermediate, which together with the isolated product (2S,5R)-N-benzyl-2-carboxy-5-[[[2-hydroxy-1,1-bis(hydroxymethyl) ethyl]amino]carbonyl]pyrrolidine (3) suggested Tris as a competitive nucleophile to water. The increased enantioselectivity seen in the produced (2R,5S)-N-benzyl-2-methoxy-carbonyl-5-carboxypyrrolidine (2) was explained by the preference of Tris to react faster with one of the diastereomeric acyl enzymes over the other.

Human immunodeficiency viral protease is catalytically active as a fusion protein: characterization of the fusion and native enzymes produced in Escherichia coli.

Processing of the gag and pol gene precursor proteins of retroviruses is essential for the production of mature infectious virions. The processing is directed by a viral protease that itself is part of these precursors and is presumed to cleave itself autocatalytically. To facilitate study of this process, the protease was produced as a fusion protein in Escherichia coli. In this construct, the 10,793-Da protease was preceeded by two copies of a modified IgG binding domain derived from protein A. The IgG binding domain was linked to the protease by an Asp-Pro peptide bond which could not be cleaved by the viral protease. A dimer of the 25,400-Da fusion protein was catalytically active, specifically cleaving a substrate peptide at the correct Tyr-Pro bond. Thus, the fusion protein could serve as a model of the viral gag-pol polyprotein. The finding that the fusion protein was catalytically active supports the suggestion that a gag-pol dimer can initiate a proteolytic cascade after budding of the immature virus. The fusion protein also provided a source of authentic protease. The protease was released from the fusion construct by incubation with formic acid, cleaving the Asp-Pro linkage which had been inserted between the IgG binding domain and the protease.