Structural and Mutational Analyses of Aspergillus fumigatus SidA: A Flavin-Dependent N-hydroxylating Enzyme

Fedkenheuer, Michael Gerald

27 August 2012

SidA from Aspergillus fumigatus is an N-hydroxylating monooxygenase that catalyzes the committed step in siderophore biosynthesis. This gene is essential for virulence making it an excellent drug target. In order to design an inhibitor against SidA a greater understanding of the mechanism and structure is needed. We have determined the crystal structure of SidA in complex with NADP+, Ornithine, and FAD at 1.9 ? resolution. The crystal structure has provided insight into substrate and coenzyme selectivity as well as residues essential for catalysis. In particular, we have chosen to study the interactions of Arg 279, shown to interact with the 2'phosphate of the adenine moiety of NADP+ as well as the adenine ring itself. The mutation of this residue to alanine makes the enzyme have little to no selectivity between coenzymes NADPH and NADH which supports the importance of the ionic interaction between Arg279 and the 2'phosphate. Additionally, the mutant enzyme is significantly more uncoupled than WT enzyme with NADPH. We see that the interactions of the guanadinyl group of Arg279 and the adenine ring are also important because KM and Kd values for the mutant enzyme are shifted well above those of wild type with coenzyme NADH. The data is further supported by studies on the reductive and oxidative half reactions. We have also explored the allosteric effect of L-arginine. We provide evidence that an enzyme/coenzyme/L-arginine complex is formed which improves coupling, oxygen reactivity, and reduction in SidA; however more work is needed to fully understand the role of L-arginine as an allosteric effector. / Master of Science in Life Sciences

N-hydroxylating Monooxygenases

Af SidA

hydroxylation

flavin

siderophore

Structural and Mechanistic Studies on N-Hydroxylating Monooxygenases Involved in Siderophore Biosynthesis

Robinson, Reeder McNeil

22 April 2015

N-Hydroxylating monooxygenases (NMOs) are flavin dependent enzymes that primarily catalyze the hydroxylation of L-ornithine or L-lysine. This is the first, committed step to siderophore biosynthesis. Pathogenic microbes including Aspergillus fumigatus and Mycobacterium tuberculosis secrete these low molecular weight compounds in order to uptake FeIII from their hosts for their metabolic needs when establishing infection. Therefore, members of this family of enzymes represent novel drug targets for the development of antibiotics. Here, we present the detailed functional and structural analysis of the L-ornithine monooxygenase SidA from Aspergillus fumigatus and the L-lysine monooxygenases MbsG from Mycobacterium smegmatis and NbtG from Nocardia farcinica. The detailed chemical mechanism for flavin oxidation in SidA was elucidated for formation of the C4a-hydroperoxyflavin, deprotonation of L-ornithine, and for the chemical steps of hydrogen peroxide elimination and water elimination. This was performed through a combination of kinetic isotope effect, pH, and density functional theory studies. Also, important residues involved in substrate binding and catalysis were characterized using site-directed mutagenesis for both SidA and NbtG. These include residues involved in coenzyme selectivity, substrate binding, and residues important in C4a-hydroperoxyflavin stabilization and flavin oxidation. The kinetic mechanisms of the L-lysine monooxygenases MbsG and NbtG were characterized which show unique differences with SidA. These include differences in coenzyme selectivity, and C4a-hydroperoxyflavin stabilization. Lastly, the three-dimensional structure of NbtG was solved using X-ray crystallography which is the first structure of a lysine monooxygenase. The structure shows the NADPH-binding domain is rotated ~30° relative to the FAD-binding domain which occludes NADP+ binding in NbtG. Unlike SidA, NbtG does not stabilize a C4a-hydroperoxyflavin and this occlusion observed in the structure might explain this difference. This highlights both the structural and mechanistic diversities among NMOs and the data presented here provides valuable information for the future development of specific inhibitors of NMOs. / Ph. D.

flavin-dependent monooxygenases

N-hydroxylating

C4a-hydroperoxyflavin

siderophore

enzyme mechanism

X-ray crystallography

Mechanistic Studies of Flavin-Dependent Monooxygenases Involved in Bacterial Defense and Plant Metabolism

Lyons, Noah Scott

12 March 2025

Flavin-dependent monooxygenases (FMOs) are a large family of enzymes found in microbes, plants, animals, and humans involved in defense pathways, xenobiotic metabolism, and natural product biosynthesis. One class of FMOs, Class B, carries out the oxidation of heteroatomic substrates, via hydroxylation, S-oxygenation, Baeyer-Villiger oxidation, and decarboxylation, using NAD(P)H as a coenzyme. In this dissertation, the characterization of several FMOs from bacteria and plants is described. The putrescine N-monooxygenase (NMO) FbsI from Acinetobacter baumannii is involved in the fimsbactin siderophore biosynthetic pathway, a virulence factor that allows acquisition of free iron from a human host by a pathogen. We show that putrescine is hydroxylated to form N-hydroxyputrescine and is favored over the aliphatic diamine cadaverine and amino acid L-ornithine. The three-dimensional structure of FbsI was solved and shown to have similarities to other NMOs, and characterization of active site mutants revealed residues essential for catalysis and cofactor specificity. The flavin-dependent S-monooxygenase TvMAS1 from the society garlic Tulbaghia violacea has been implicated in the production of marasmin, a natural product with human health benefits. We find that TvMAS1 has a broad substate scope among thiol and sulfide-containing compounds, particularly L-cysteine derivatives. Additionally, we show that S-allyl-L-cysteine is the preferred substrate and propose TvMAS1 to primarily have a physiological role in allicin, not marasmin biosynthesis. Lastly, we characterized the auxin-producing FMO YUC10 from Arabidopsis thaliana and showed the enzyme to only have steady-state activity with aromatic α-keto acids indole-3-pyruvic acid (IPA) and phenylpyruvic acid (PPA). We also propose that a C4a-peroxyflavin intermediate acts as a nucleophile to perform the oxidative decarboxylation on IPA and PPA. The work in this dissertation fills several knowledge gaps among bacterial and plant FMOs and with the established mechanisms aims to guide future drug discovery, green chemistry, and agricultural bioengineering efforts. / Doctor of Philosophy / The water-soluble vitamin riboflavin, also known as Vitamin B2, is an essential nutrient with numerous human health benefits and known for its characteristic yellow-orange color. The major role of riboflavin is in the synthesis of the coenzymes flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD), which are involved in biological processes such as energy metabolism and detoxification. Flavoenzymes are proteins found in all living organisms that use either FMN or FAD to facilitate otherwise unfavorable biochemical reactions in living systems. One class of flavoenzymes, known as flavin-dependent monooxygenases (FMOs), carries out oxidation-reduction reactions on an array of small molecules with the aid of molecular oxygen. In this dissertation, we present the characterization of three FMOs and propose their roles in nature. The pathogenic bacterium Acinetobacter baumannii can survive in human hosts using several virulence factors, one of which are siderophores – molecules that scavenge iron and transport it back to the organism. We determined that the enzyme FbsI hydroxylates the amine-containing substrate putrescine into N-hydroxyputrescine, a building block of the A. baumannii siderophore fimsbactin A. By solving the enzyme's three-dimensional structure and characterizing its reaction mechanism, we hope to guide future drug discovery studies of this target. We also describe the role of two FMOs from the society garlic Tulbaghia violacea (TvMAS1) and the thale cress Arabidopsis thaliana (YUC10). We show that TvMAS1 performs S-oxidation of S-allyl-L-cysteine to alliin with high efficiency, implicating a role in the production of allicin - a flavorful compound with health benefits. Finally, we show that YUC10 is involved in the production of auxin, a plant hormone that directs growth and development. A novel chemical mechanism for the YUCCAs is proposed, providing insight from in vitro experiments to guide in vivo findings. Our work with TvMAS1 and YUC10 will help guide future protein engineering and green chemistry efforts in the agricultural industry.

Flavin-dependent monooxygenases

enzyme mechanism

siderophores

N-hydroxylating

Acinetobacter baumannii

S-oxygenating

marasmin

Tulbaghia violacea

YUCCA

auxin

Arabidopsis thaliana