Crystal structures of Aspergillus oryzae Rib2 deaminase: the functional mechanism involved in riboflavin biosynthesis.

Riboflavin serves as the direct precursor of the FAD/FMN coenzymes and is biosynthesized in most prokaryotes, fungi and plants. Fungal Rib2 possesses a deaminase domain for deamination of pyrimidine in the third step of riboflavin biosynthesis. Here, four high-resolution crystal structures of a Rib2 deaminase from Aspergillus oryzae (AoRib2) are reported which display three distinct occluded, open and complex forms that are involved in substrate binding and catalysis. In addition to the deaminase domain, AoRib2 contains a unique C-terminal segment which is rich in charged residues. Deletion of this unique segment has no effect on either enzyme activity or protein stability. Nevertheless, the C-terminal αF helix preceding the segment plays a role in maintaining protein stability and activity. Unexpectedly, AoRib2 is the first mononucleotide deaminase found to exist as a monomer, perhaps due to the assistance of its unique longer loops (Lß1-ß2, LαB-ß3 and LαC-ß4). These results form the basis for a molecular understanding of riboflavin biosynthesis in fungi and might assist in the development of antibiotics.

Evolution of archaeal Rib7 and eubacterial RibG reductases in riboflavin biosynthesis: Substrate specificity and cofactor preference.

Archaeal/fungal Rib7 and eubacterial RibG possess a reductase domain for ribosyl reduction in the second and third steps, respectively, of riboflavin biosynthesis. These enzymes are specific for an amino and a carbonyl group of the pyrimidine ring, respectively. Here, several crystal structures of Methanosarcina mazei Rib7 are reported at 2.27-1.95 Šresolution, which are the first archaeal dimeric Rib7 structures. Mutational analysis displayed that no detectable activity was observed for the Bacillus subtilis RibG K151A, K151D, and K151E mutants, and the M. mazei Rib7 D33N, D33K, and E156Q variants, while 0.1-0.6% of the activity was detected for the M. mazei Rib7 N9A, S29A, D33A, and D57N variants. Our results suggest that Lys151 in B. subtilis RibG, while Asp33 together with Arg36 in M. mazei Rib7, ensure the specific substrate recognition. Unexpectedly, an endogenous NADPH cofactor is observed in M. mazei Rib7, in which the 2'-phosphate group interacts with Ser88, and Arg91. Replacement of Ser88 with glutamate eliminates the endogenous NADPH binding and switches preference to NADH. The lower melting temperature of ∼10 °C for the S88E and R91A mutants suggests that nature had evolved a tightly bound NADPH to greatly enhance the structural stability of archaeal Rib7.

Evolution of vitamin B2 biosynthesis: eubacterial RibG and fungal Rib2 deaminases.

Eubacterial RibG and yeast Rib2 possess a deaminase domain for pyrimidine deamination in the second and third steps, respectively, of riboflavin biosynthesis. These enzymes are specific for ribose and ribitol, respectively. Here, the crystal structure of Bacillus subtilis RibG in complex with a deaminase product is reported at 2.56 Å resolution. Two loops move towards the product on substrate binding, resulting in interactions with the ribosyl and phosphate groups and significant conformational changes. The product carbonyl moiety is bent out of the pyrimidine ring to coordinate to the catalytic zinc ion. Such distortions in the bound substrate and product may play an essential role in enzyme catalysis. The yeast Rib2 structure was modelled and a mutational analysis was carried out in order to understand the mechanism of substrate recognition in these two enzymes. Detailed structural comparisons revealed that the two consecutive carbonyl backbones that occur prior to the PCXXC signature constitute a binding hole for the target amino group of the substrate. This amino-binding hole is essential in B. subtilis RibG and is also conserved in the RNA/DNA-editing deaminases.