Novel molecular architecture of the multimeric archaeal PEP-synthase homologue (MAPS) from Staphylothermus marinus.

The phosphoenolpyruvate (PEP)-synthases belong to the family of structurally and functionally related PEP-utilizing enzymes. The only archaeal member of this family characterized thus far is the Multimeric Archaeal PEP-Synthase homologue from Staphylothermus marinus (MAPS). This protein complex differs from the bacterial and eukaryotic representatives characterized to date in its homomultimeric, as opposed to dimeric or tetrameric, structure. We have probed the molecular architecture of MAPS using limited proteolytic digestion in conjunction with electron microscopic, biochemical, and biophysical techniques. The 2.2 MDa particle was found to be organized in a concentric fashion. The 93.7 kDa monomers possess a pronounced tripartite domain structure and are arranged such that the N-terminal domains form an outer shell, the intermediate domains form an inner shell, and the C-terminal domains form a core structure responsible for the assembly into a multimeric complex. The core domain was shown to be capable of assembling into the native multimer by recombinant expression in Escherichia coli. Deletion mutants as well as a synthetic peptide were investigated for their state of oligomerization using native polyacrylamide gel electrophoresis, molecular sieve chromatography, analytical ultracentrifugation, circular dichroism (CD) spectroscopy, and chemical cross-linking. Our data confirmed the existence of a short C-terminal, alpha-helical oligomerization motif that had been suggested by multiple sequence alignments and secondary structure predictions. We propose that this motif bundles the monomers into six groups of four. An additional formation of 12 dimers between globular domains from different bundles leads to the multimeric assembly. According to our model, each of the six bundles of globular domains is positioned at the corners of an imaginary octahedron, and the helical C-terminal segments are oriented towards the centre of the particle. The edges of the octahedron represent the dimeric contacts. Phylogenetic analysis suggests that the ancient predecessor of this family of enzymes contained the C-terminal oligomerization motif as a feature that was preserved in some hyperthermophiles.

Structural studies on the 2.25-MDa homomultimeric phosphoenolpyruvate synthase from Staphylothermus marinus.

The phosphoenolpyruvate synthase of the hyperthermophilic archaeon Staphylothermus marinus forms an unusually large homomultimeric complex of 93 kDa subunits. Electron image analysis of negatively stained and low-dose unstained preparations showed that the complex has a single, stable characteristic view and a well-preserved core with threefold rotational symmetry. The periphery of the assembly is composed of a nebulous, possibly flexible, component. Mass measurements by scanning transmission electron microscopy yielded a molecular weight of 2250 +/- 230 kDa, confirming the well-defined nature of the structure and indicating that it is composed of 24 +/- 2.5 subunits. The stability and symmetry of the characteristic projection views suggest a polyhedral three-dimensional architecture. The novel quaternary arrangement of this enzyme might be a consequence of its adaptation to an extreme environment.

Primary structure of a multimeric protein, homologous to the PEP-utilizing enzyme family and isolated from a hyperthermophilic archaebacterium.

A large protein complex (approx. 2000 kDa) was found in the cytosol of the hyperthermophilic archaebacterium Staphylothermus marinus. The purified protein was shown to be a homomultimer of 93 kDa subunits, the primary structure of which was determined by nucleotide sequence analysis. The protein belongs to the family of phosphoenolpyruvate-utilizing enzymes and represents the first member characterized in archaebacteria. Its homomultimeric organisation differs from the typically dimeric structure of its eubacterial and eukaryotic counterparts.