INVESTIGADORES
GONZALEZ FLECHA Francisco Luis
congresos y reuniones científicas
Título:
Reversible unfolding of CopA, a thermophilic P1B-type membrane ATPase from Archaeglobus fulgidus.
Autor/es:
ERNESTO A. ROMAN; JOSÉ M ARGÜELLO; F. LUIS GONZÁLEZ FLECHA
Lugar:
Baltimore USA
Reunión:
Congreso; 51th Annual Meeting of the Biophysical Society; 2007
Institución organizadora:
Biophysical Society
Resumen:
Folding and stability are determinant elements of protein biological functions. The stability of membrane proteins is poorly understood. Highly stable polytopic membrane proteins from extremophilic organisms might provide convenient models to understand stability determinants. The aim of this work was to characterize chemical denaturation of CopA, a thermophilic PIB-type Cu-ATPase from Archaeglobus fulgidus. CopA was heterologously expressed in Escherichia coli, solubilized in dodecylmaltoside, affinity purified, and obtained in a lipid/detergent micellar form. Isolated CopA retained thermophilic characteristics with maximum activity at 75°C. The effects of guanidinium chloride (GndHCl) and sodium dodecyl sulfate (SDS) on enzyme activity, Trp fluorescence, and circular dichroism were analyzed. Our results show that GndHCl decreases Trp fluorescence and [θ]222nm in a reversible manner, both with Cm values of 3.6 M. In parallel to these changes, CopA was reversibly inactivated. When CopA was incubated with SDS at concentrations below cmc, the activity and the Trp fluorescence decayed reversibly, with a Cm value of 0.89 mM. However, [θ]222nm remained unchanged. Estimated unfolding ΔG0H2O were similar for both denaturants, although the unfolded states might differ in secondary structure. Observed GndHCl Cm values were higher than those reported for mesophilic membrane proteins. These results suggest that thermophilic membrane proteins are more stable than their mesophilic counterparts and retain their stability even when heterologously expressed. Moreover, these findings point out the suitability of extremophilic membrane proteins for thermodynamic folding studies. Supported by NSF Grant OISE-0436435 to JMA, and UBACyT B089 and ANPCyT Grant PICT-11138 to FLGF.