Small peptide inhibitors of acetyl-peptide hydrolase having an uncommon mechanism of inhibition and a stable bent conformation.

Acyl peptide hydrolase (APEH) catalyzes the removal of acetyl-amino acids from the N-terminus of peptides and cytoplasmic proteins. Due to the role played in several diseases, and to the growing interest around N-terminal acetylation, studies on APEH structure, function, and inhibition are attracting an ever increasing attention. We have therefore screened a random tetrapeptide library, N-capped with selected groups, and identified a trifluoroacetylated tetrapeptide (CF(3)-lmph) which inhibits the enzyme with a K(i) of 24.0 ± 0.8 µM. The inhibitor is selective for APEH, shows an uncommon uncompetitive mechanism of inhibition, and in solution adopts a stable bent conformation. CF(3)-lmph efficiently crosses cell membranes, blocking the cytoplasmic activity of APEH; however, it triggers a mild pro-apoptotic effect as compared to other competitive and noncompetitive inhibitors. The unusual inhibition mechanism and the stable structure make the new compound a novel tool to investigate enzyme functions and a useful scaffold to develop more potent inhibitors.

Structural and functional insights into Aeropyrum pernix OppA, a member of a novel archaeal OppA subfamily.

In this study we gain insight into the structural and functional characterization of the Aeropyrum pernix oligopeptide-binding protein (OppA(Ap)) previously identified from the extracellular medium of an Aeropyrum pernix cell culture at late stationary phase. OppA(Ap) showed an N-terminal Q32 in a pyroglutamate form and C-terminal processing at the level of a threonine-rich region probably involved in protein membrane anchoring. Moreover, the OppA(Ap) protein released into the medium was identified as a "nicked" form composed of two tightly associated fragments detachable only under strong denaturing conditions. The cleavage site E569-G570 seems be located on an exposed surface loop that is highly conserved in several three-dimensional (3D) structures of dipeptide/oligopeptide-binding proteins from different sources. Structural and biochemical properties of the nicked protein were virtually indistinguishable from those of the intact form. Indeed, studies of the entire bacterially expressed OppA(Ap) protein owning the same N and C termini of the nicked form supported these findings. Moreover, in the middle exponential growth phase, OppA(Ap) was found as an intact cell membrane-associated protein. Interestingly, the native exoprotein OppA(Ap) was copurified with a hexapeptide (EKFKIV) showing both lysines methylated and possibly originating from an A. pernix endogenous stress-induced lipoprotein. Therefore, the involvement of OppA(Ap) in the recycling of endogenous proteins was suggested to be a potential physiological function. Finally, a new OppA from Sulfolobus solfataricus, SSO1288, was purified and preliminarily characterized, allowing the identification of a common structural/genetic organization shared by all "true" archaeal OppA proteins of the dipeptide/oligopeptide class.

A highly selective oligopeptide binding protein from the archaeon Sulfolobus solfataricus.

SSO1273 of Sulfolobus solfataricus was identified as a cell surface-bound protein by a proteomics approach. Sequence inspection of the genome revealed that the open reading frame of sso1273 is associated in an operon-like structure with genes encoding all the remaining components of a canonical protein-dependent ATP-binding cassette (ABC) transporter. sso1273 gene expression and SSO1273 protein accumulation on the cell surface were demonstrated to be strongly induced by the addition of a peptide mixture (tryptone) to the culture medium. The native protein was obtained in multimeric form, mostly hexameric, under the purification conditions used, and it was characterized as an oligopeptide binding protein, named S. solfataricus OppA (OppA(Ss)). OppaA(Ss) possesses typical sequence patterns required for glycosylphosphatidylinositol lipid anchoring, resulting in an N-linked glycoprotein with carbohydrate moieties likely composed of high mannose and/or hybrid complex carbohydrates. OppA(Ss) specifically binds oligopeptides and shows a marked selectivity for the amino acid composition of substrates when assayed in complex peptide mixtures. Moreover, a truncated version of OppA(Ss), produced in recombinant form and including the putative binding domain, showed a low but significant oligopeptide binding activity.

Phenylmethanesulfonyl fluoride inactivates an archaeal superoxide dismutase by chemical modification of a specific tyrosine residue. Cloning, sequencing and expression of the gene coding for Sulfolobus solfataricus superoxide dismutase.

The gene encoding the superoxide dismutase from the hyperthermophilic archaeon Sulfolobus solfataricus (SsSOD) was cloned and sequenced and its expression in Escherichia coli obtained. The chemicophysical properties of the recombinant SsSOD were identical with those of the native enzyme. The recombinant SsSOD possessed a covalent modification of Tyr41, already observed in native SsSOD [Ursby, T., Adinolfi, B.S., Al-Karadaghi, S., De Vendittis, E. & Bocchini, V. (1999) J. Mol. Biol. 286, 189--205]. HPLC analysis of SsSOD samples prepared from cells treated or not with phenylmethanesulfonyl fluoride (PhCH(2)SO(2)F), a protease inhibitor routinely added during the preparation of cell-free extracts, showed that the modification was caused by PhCH(2)SO(2)F. Refinement of the crystal model of SsSOD confirmed that a phenylmethanesulfonyl moiety was attached to the hydroxy group of Tyr41. PhCH(2)SO(2)F behaved as an irreversible inactivator of SsSOD; in fact, the specific activity of both native and recombinant enzyme decreased as the percentage of modification increased. The covalent modification caused by PhCH2SO2F reinforced the heat stability of SsSOD. These results show that Tyr41 plays an important role in the enzyme activity and the maintenance of the structural architecture of SsSOD.