AI Article Synopsis
- NSAAR from Geobacillus kaustophilus (GkNSAAR) requires a divalent metal ion, specifically Co(2+), to achieve optimal enzymatic activity, showcasing its importance in biological processes.
- The protein exhibits a tetrameric structure with an elongated shape and retains certain oligomerization characteristics found in other members of the enolase superfamily, although it doesn’t form octamers like some of its relatives.
- GkNSAAR displays significant stability under various conditions, maintaining a functional structure primarily composed of alpha-helices, while Co(2+) slightly influences its secondary structure but does not greatly impact protein stability.
Article Abstract
The N-succinylamino acid racemases (NSAAR) belong to the enolase superfamily and they are large homooctameric/hexameric species that require a divalent metal ion for activity. We describe the structure and stability of NSAAR from Geobacillus kaustophilus (GkNSAAR) in the absence and in the presence of Co(2+) by using hydrodynamic and spectroscopic techniques. The Co(2+), among other assayed divalent ions, provides the maximal enzymatic activity at physiological pH. The protein seems to be a tetramer with a rather elongated shape, as shown by AU experiments; this is further supported by the modeled structure, which keeps intact the largest tetrameric oligomerization interfaces observed in other homooctameric members of the family, but it does not maintain the octameric oligomerization interfaces. The native functional structure is mainly formed by alpha-helix, as suggested by FTIR and CD deconvoluted spectra, with similar percentages of structure to those observed in other protomers of the enolase superfamily. At low pH, the protein populates a molten-globule-like conformation. The GdmCl denaturation occurs through a monomeric intermediate, and thermal denaturation experiments indicate a high thermostability. The presence of the cofactor Co(2+) did alter slightly the secondary structure, but it did not modify substantially the stability of the protein. Thus, GkNSAAR is one of the few members of the enolase family whose conformational propensities and stability have been extensively characterized.
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