Molecular basis for differential nucleotide binding of the nucleotide-binding domain of ABC-transporter CvaB

The cytoplasmic membrane protein CvaB, involved in colicin V secretion in Escherichia coli, belongs to the ABC-transporter family in which ATP hydrolysis is typically the driving force for substrate transport. However, our previous studies indicated that the nucleotide-binding domain of CvaB could also bind and hydrolyze GTP and, indeed, highly preferred GTP over ATP at low temperatures. In this study, we have examined the molecular basis of this preference. Sequence alignment and homology modeling of the CvaB nucleotide-binding domain predicted that the aromatic stacking region of CvaB (Y501DSQ loop) had a role in the differential binding of nucleotides, and Ser503 and Gln504 provided potential hydrogen bonds to GTP but not to ATP. Site-directed mutagenesis of the Y501DSQ loop, mutations S503A, Q504L, and double mutation S503A/Q504L, was made to test the predicted hydrogen bonds with GTP. The double mutation S503A/Q504L increased the affinity for ATP by 6-fold, whereas the affinity for GTP was reduced slightly: the ATP/GTP-binding ratio increased about 10-fold. The temperature effect assays on nucleotide binding and hydrolysis further indicated that the double mutant protein had largely eliminated the difference for substrates ATP and GTP, and behaved more similarly to the NBD of typical ABC-transporter HlyB. Therefore, we conclude that Ser503 and Gln504 in aromatic stacking region of CvaB block the ATP binding and are important for the GTP-binding preference.