RANBP2 mutation causing autosomal dominant acute necrotizing encephalopathy attenuates its interaction with COX11.

PURPOSE: Autosomal dominant acute necrotizing encephalopathy (ADANE) is caused by missense mutations in the gene encoding Ran-binding protein 2 (RANBP2), a nuclear pore protein regulating mitochondrial localization and function. Previous studies have found that RANBP2 binds to COX11 and suppresses its inhibitory activity over hexokinase1. To further elucidate mitochondrial dysfunction in ADANE, we analyzed the interaction between mutated RANBP2 and COX11. METHODS: We extracted cDNA from a patient and constructed pGEX wild-type or mutant-type vectors including RANBP2 c.1754C>T, the commonest variant in ADANE. We transformed E. coli competent cells with the vectors and had them express GST-RANBP2 recombinant protein, and conducted a pull-down assay of RANBP2 and COX11. RESULTS: The amount of COX11 bound to mutated RANBP2 was significantly smaller than that bound to the wild-type RANBP2. CONCLUSION: Mutated RANBP2 had an attenuated binding ability to COX11. Whether this change indeed decreases ATP production remains to be further explored.

Expression and Purification of the VpDef Defensin in Escherichia coli using the Small Metal-Binding Proteins CusF3H+ and SmbP.

BACKGROUND: The heterologous production of antimicrobial peptides in bacterial models can produce insoluble proteins due to the lack of proper folding. Fusion proteins have been used to increase the expression and solubility of these types of proteins with varying degrees of success. OBJECTIVES: Here, we demonstrate the use of the small metal-binding proteins CusF3H+ (9.9kDa) and SmbP (9.9kDa) as fusion partners for the soluble expression of the bioactive antimicrobial peptide VpDef(6.9 kDa) in Escherichia coli. METHODS: The recombinant VpDef (rVpDef) peptide was expressed as a translational fusion with CusF3H+ and SmbP in Escherichia coli SHuffle under different small-scale culture conditions. The best conditions were applied to 1-liter cultures, with subsequent purification of the recombinant protein through IMAC chromatography. The recombinant protein was digested using enterokinase to liberate the peptide from the fusion protein, and a second IMAC chromatography step removed the fusion protein. The purified peptide was tested against two Gram-positive and two Gram-negative bacteria. RESULTS: The use either of CusF3H+ or of SmbP results in recombinant proteins that are found in the soluble fraction of the bacterial lysate; these recombinant proteins are easily purified through IMAC chromatography, and rVpDef is readily separated following enterokinase treatment. The purified rVpDef peptide exhibits antimicrobial properties against both Gram-positive and Gram-negative. CONCLUSION: Use of the fusion proteins CusF3H+ and SmbP results in production of a soluble recombinant protein containing the antimicrobial peptide rVpDef that is correctly folded and that retains its antimicrobial properties once purified.