Multinuclear NMR and UV–Vis spectroscopy of site directed mutants of the diabetes drug target protein mitoNEET suggest that folding is intimately coupled to iron-sulfur cluster formation
 

Multinuclear NMR and UV–Vis spectroscopy of site directed mutants of the diabetes drug target protein mitoNEET suggest that folding is intimately coupled to iron-sulfur cluster formation

Publication date: Available online 4 December 2015
Source:Inorganic Chemistry Communications</br>
Author(s): S.K. Benson, K.M. Boyce, R.M. Bunker, N.B. Collins, K.J. Daily, A.S. Esway, G.T. Gilmore, C.W. Hartzler, G.P. Howard, N.A. Kasmar, K.J. Kennedy, B.L. King, T.N. Kordahi, T.A. Mattioli, D.M. Pugh, L.A. Ray, S.L. Ross, M.H. Torcasio, D.P. Webber, D.L. Morris, T.C. Leeper</br>
Further understanding of the mitochondrial protein mitoNEET could lead to advancements in drug design for the treatment of mitochondrial diseases. Previous studies have shown that mitoNEET's iron-sulfur cluster plays a key role in its biochemistry. In order to gain insight into the structural stability and folding of mitoNEET's iron-sulfur clusters, mutants were created using site-directed mutagenesis. NMR and UV–Vis spectroscopic analysis of these mutants suggested that half had successfully hindered protein folding that in turn, increased lability and eventually loss of functional iron-sulfur clusters. Understanding the significance of this coupling of lability to misfolding could be key to learning mitoNEET‘s mode of action in mitochondria. These findings may allow mitoNEET to be utilized for therapeutics and a better understanding of mitochondrial-based diseases.
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