Abstract
Nicotinamide adenine dinucleotide synthetases (NADS) catalyze the amidation of nicotinic acid adenine dinucleotide (NAAD) to yield the enzyme cofactor nicotinamide adenine dinucleotide (NAD). Here we describe the crystal structures of the ammonia-dependent homodimeric NADS from Escherichia coli alone and in complex with natural substrates and with the reaction product NAD. The structures disclosed two NAAD/NAD binding sites at the dimer interface and an adenosine triphosphate (ATP) binding site within each subunit. Comparison with the Bacillus subtilis NADS showed pronounced chemical differences in the NAAD/NAD binding sites and less prominent differences in the ATP binding pockets. In addition, the E. coli NADS structures revealed unexpected dynamical rearrangements in the NAAD/NAD binding pocket upon NAAD-to-NAD conversion, which define a catalysis state and a substrate/product exchange state. The two states are adopted by concerted movement of the nicotinysyl moieties of NAAD and NAD, Phe-170, and residues 224-228, which may be triggered by differential coordination of a magnesium ion to NAAD and NAD. Phylogenetic structure comparisons suggest that the present results are relevant for designing species-specific antibiotics.
Highlights
Nicotinamide adenine dinucleotide (NAD)1 is a ubiquitous carrier of reduction equivalents and functions as a cofactor in numerous metabolic reactions
It is important to note that the change in conformation of ecoNADS region 224 –228 and of Phe-170 correlates with the presence of Mg2ϩ-I, which we have shown above to be involved in orientation of the substrate nicotinic acid adenine dinucleotide (NAAD), but which is lacking when NAD is present
We presented the high resolution crystal structures of ecoNADS as well as the structures of the enzyme with various substrates and products
Summary
Nicotinamide adenine dinucleotide (NAD) is a ubiquitous carrier of reduction equivalents and functions as a cofactor in numerous metabolic reactions. NADSs from several prokaryotes, including Bacillus subitilis (bsu) [5], Escherichia coli (eco) [6, 7], and Mycobacterium tuberculosis (mtu) [8] have been cloned and characterized. Both ecoNADS and bsuNADS exhibit a clear preference for ammonia over glutamine [2, 5, 7], whereas the mtuNADS can use both glutamine and ammonia as amide donors [8]. Eukaryotic NADSs confer an additional N-terminal domain with nitrilase activity, which enables them to use glutamine as an amide donor [10]
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