Characterization of a Glycyl-Specific TET Aminopeptidase Complex from Pyrococcus horikoshii.

The TET peptidases are large self-compartmentalized complexes that form dodecameric particles. These metallopeptidases, members of the M42 family, are widely distributed in prokaryotes. Three different versions of TET complexes, with different substrate specificities, were found to coexist in the cytosol of the hyperthermophilic archaeon Pyrococcus horikoshii In the present work, we identified a novel type of TET complex that we named PhTET4. The recombinant PhTET4 enzyme was found to self-assemble as a tetrahedral edifice similar to other TET complexes. We determined PhTET4 substrate specificity using a broad range of monoacyl chromogenic and fluorogenic compounds. High-performance liquid chromatographic peptide degradation assays were also performed. These experiments demonstrated that PhTET4 is a strict glycyl aminopeptidase, devoid of amidolytic activity toward other types of amino acids. The catalytic efficiency of PhTET4 was studied under various conditions. The protein was found to be a hyperthermophilic alkaline aminopeptidase. Interestingly, unlike other peptidases from the same family, it was activated only by nickel ions.IMPORTANCE We describe here the first known peptidase displaying exclusive activity toward N-terminal glycine residues. This work indicates a specific role for intracellular glycyl peptidases in deep sea hyperthermophilic archaeal metabolism. These observations also provide critical evidence for the use of these archaeal extremozymes for biotechnological applications.

TET peptidases: A family of tetrahedral complexes conserved in prokaryotes.

The TET peptidases are large polypeptide destruction machines present among prokaryotes. They form 12-subunits hollow tetrahedral particles, and belong to the family of M42 metallo-peptidases. Structural characterization of various archaeal and bacterial complexes has revealed a unique mechanism of internal compartmentalization and peptide trafficking that distinguishes them from the other oligomeric peptidases. Different versions of the TET complex often co-exist in the cytosol of microorganisms. In depth enzymatic studies have revealed that they are non-processive cobalt-activated aminopeptidases and display contrasting substrate specificities based on the properties of the catalytic chambers. Recent studies have shed light on the assembly mechanism of homo and hetero-dodecameric TET complexes and shown that the activity of TET aminopeptidase towards polypeptides is coupled with its assembly process. These findings suggested a functional regulation based on oligomerization control in vivo. This review describes a current knowledge on M42 TET peptidases biochemistry and discuss their possible physiological roles. This article is a part of the Special Issue entitled: «A potpourri of proteases and inhibitors: from molecular toolboxes to signalling scissors¼.

Small-angle neutron scattering reveals the assembly mode and oligomeric architecture of TET, a large, dodecameric aminopeptidase.

The specific self-association of proteins into oligomeric complexes is a common phenomenon in biological systems to optimize and regulate their function. However, de novo structure determination of these important complexes is often very challenging for atomic-resolution techniques. Furthermore, in the case of homo-oligomeric complexes, or complexes with very similar building blocks, the respective positions of subunits and their assembly pathways are difficult to determine using many structural biology techniques. Here, an elegant and powerful approach based on small-angle neutron scattering is applied, in combination with deuterium labelling and contrast variation, to elucidate the oligomeric organization of the quaternary structure and the assembly pathways of 468 kDa, hetero-oligomeric and symmetric Pyrococcus horikoshii TET2-TET3 aminopeptidase complexes. The results reveal that the topology of the PhTET2 and PhTET3 dimeric building blocks within the complexes is not casual but rather suggests that their quaternary arrangement optimizes the catalytic efficiency towards peptide substrates. This approach bears important potential for the determination of quaternary structures and assembly pathways of large oligomeric and symmetric complexes in biological systems.

The TET2 and TET3 aminopeptidases from Pyrococcus horikoshii form a hetero-subunit peptidasome with enhanced peptide destruction properties.

TET aminopeptidases assemble as large homo-dodecameric complexes. The reason why prokaryotic genomes often encode a diverse set of TET peptidases homologues remains unclear. In the archaeon Pyrococcus horikoshii, PhTET1, PhTET2 and PhTET3 homo-oligomeric particles have been proposed to work in concert to breakdown intracellular polypeptides. When coexpressed in Escherichia coli, the PhTET2 and PhTET3 proteins were found to assemble efficiently as heteromeric complexes. Biophysical analysis demonstrated that these particles possess the same quaternary structure as the homomeric TET dodecamers. The same hetero-oligomeric complexes were immunodetected in P. horikoshii cell extracts analysed by sucrose gradient fractionation and ion exchange chromatography. The biochemical activity of a purified hetero-oligomeric TET particle, assessed on chromogenic substrates and on a complex mixture of peptides, reveals that it displays higher efficiency than an equivalent combination of homo-oligomeric TET particles. Interestingly, phylogenetic analysis shows that PhTET2 and PhTET3 are paralogous proteins that arose from gene duplication in the ancestor of Thermococcales. Together, these results establish that the PhTET2 and PhTET3 proteins are two subunits of the same enzymatic complex aimed at the destruction of polypeptidic chains of very different composition. This is the first report for such a mechanism intended to improve multi-enzymatic complex efficiency among exopeptidases.

Pyrococcus horikoshii TET2 peptidase assembling process and associated functional regulation.

Tetrahedral (TET) aminopeptidases are large polypeptide destruction machines present in prokaryotes and eukaryotes. Here, the rules governing their assembly into hollow 12-subunit tetrahedrons are addressed by using TET2 from Pyrococcus horikoshii (PhTET2) as a model. Point mutations allowed the capture of a stable, catalytically active precursor. Small angle x-ray scattering revealed that it is a dimer whose architecture in solution is identical to that determined by x-ray crystallography within the fully assembled TET particle. Small angle x-ray scattering also showed that the reconstituted PhTET2 dodecameric particle displayed the same quaternary structure and thermal stability as the wild-type complex. The PhTET2 assembly intermediates were characterized by analytical ultracentrifugation, native gel electrophoresis, and electron microscopy. They revealed that PhTET2 assembling is a highly ordered process in which hexamers represent the main intermediate. Peptide degradation assays demonstrated that oligomerization triggers the activity of the TET enzyme toward large polypeptidic substrates. Fractionation experiments in Pyrococcus and Halobacterium cells revealed that, in vivo, the dimeric precursor co-exists together with assembled TET complexes. Taken together, our observations explain the biological significance of TET oligomerization and suggest the existence of a functional regulation of the dimer-dodecamer equilibrium in vivo.