Structural determinants for substrate specificity of flavoenzymes oxidizing d-amino acids

Binding Affinity Determines Substrate Specificity and Enables Discovery of Substrates for N-Myristoyltransferases

Kinetic parameters (k_cat and K_m) derived from the Michaelis–Menten equation are widely used to characterize enzymes. k_cat/K_m is considered the catalytic efficiency or substrate specificity of an enzyme toward its substrate. N-Myristoyltransferases (NMTs) catalyze the N-terminal glycine myristoylation of numerous eukaryotic proteins. Surprisingly, we find that in vitro human NMT1 can accept acetyl-CoA and catalyze acetylation with k_cat and K_m values similar to that of myristoylation. However, when both acetyl-CoA and myristoyl-CoA are present in the reaction, NMT1 catalyzes almost exclusively myristoylation. This phenomenon is caused by the dramatically different binding affinities of NMT1 for myristoyl-CoA and acetyl-CoA (estimated K_d of 14.7 nM and 10.1 μM, respectively). When both are present, NMT1 is essentially entirely bound by myristoyl-CoA and thus catalyzes myristoylation exclusively. The NMT1 example highlights the crucial role of binding affinity in determining the substrate specificity of enzymes, which in contrast to the traditionally held view in enzymology that the substrate specificity is defined by k_cat/K_m values. This understanding readily explains the vast biological literature showing the coimmunoprecipitation of enzyme–substrate pairs for enzymes that catalyzes protein post-translational modifications (PTM), including phosphorylation, acetylation, and ubiquitination. Furthermore, this understanding allows the discovery of substrate proteins by identifying the interacting proteins of PTM enzymes, which we demonstrate by identifying three previously unknown substrate proteins (LRATD1, LRATD2, and ERICH5) of human NMT1/2 by mining available interactome data.

Human D-aspartate Oxidase: A Key Player in D-aspartate Metabolism

In recent years, the D-enantiomers of amino acids have been recognized as natural molecules present in all kingdoms, playing a variety of biological roles. In humans, d-serine and d-aspartate attracted attention for their presence in the central nervous system. Here, we focus on d-aspartate, which is involved in glutamatergic neurotransmission and the synthesis of various hormones. The biosynthesis of d-aspartate is still obscure, while its degradation is due to the peroxisomal flavin adenine dinucleotide (FAD)-containing enzyme d-aspartate oxidase. d-Aspartate emergence is strictly controlled: levels decrease in brain within the first days of life while increasing in endocrine glands postnatally and through adulthood. The human d-aspartate oxidase (hDASPO) belongs to the d-amino acid oxidase-like family: its tertiary structure closely resembles that of human d-amino acid oxidase (hDAAO), the enzyme that degrades neutral and basic d-amino acids. The structure-function relationships of the physiological isoform of hDASPO (named hDASPO_341) and the regulation of gene expression and distribution and properties of the longer isoform hDASPO_369 have all been recently elucidated. Beyond the substrate preference, hDASPO and hDAAO also differ in kinetic efficiency, FAD-binding affinity, pH profile, and oligomeric state. Such differences suggest that evolution diverged to create two different ways to modulate d-aspartate and d-serine levels in the human brain. Current knowledge about hDASPO is shedding light on the molecular mechanisms underlying the modulation of d-aspartate levels in human tissues and is pushing novel, targeted therapeutic strategies. Now, it has been proposed that dysfunction in NMDA receptor-mediated neurotransmission is caused by disrupted d-aspartate metabolism in the nervous system during the onset of various disorders (such as schizophrenia): the design of suitable hDASPO inhibitors aimed at increasing d-aspartate levels thus represents a novel and useful form of therapy.

Bioinformatic Analysis of the Flavin-Dependent Amine Oxidase Superfamily: Adaptations for Substrate Specificity and Catalytic Diversity

The flavin-dependent amine oxidase (FAO) superfamily consists of over 9000 nonredundant sequences represented in all domains of life. Of the thousands of members identified, only 214 have been functionally annotated to date, and 40 unique structures are represented in the Protein Data Bank. The few functionally characterized members share a catalytic mechanism involving the oxidation of an amine substrate through transfer of a hydride to the FAD cofactor, with differences observed in substrate specificities. Previous studies have focused on comparing a subset of superfamily members. Here, we present a comprehensive analysis of the FAO superfamily based on reaction mechanism and substrate recognition. Using a dataset of 9192 sequences, a sequence similarity network, and subsequently, a genome neighborhood network were constructed, organizing the superfamily into eight subgroups that accord with substrate type. Likewise, through phylogenetic analysis, the evolutionary relationship of subgroups was determined, delineating the divergence between enzymes based on organism, substrate, and mechanism. In addition, using sequences and atomic coordinates of 22 structures from the Protein Data Bank to perform sequence and structural alignments, active-site elements were identified, showing divergence from the canonical aromatic-cage residues to accommodate large substrates. These specificity determinants are held in a structural framework comprising a core domain catalyzing the oxidation of amines with an auxiliary domain for substrate recognition. Overall, analysis of the FAO superfamily reveals a modular fold with cofactor and substrate-binding domains allowing for diversity of recognition via insertion/deletions. This flexibility allows facile evolution of new activities, as shown by reinvention of function between subfamilies.

Application of an S-layer protein as a self-aggregating tag for cost-effective separation of recombinant human and yeast D-amino acid oxidases in the aqueous two-phase system

OBJECTIVE

To evaluate whether the surface layer (S-layer) protein of Lactobacillus brevis serves as a self-aggregating protein tag for cost-effective separation of human and yeast D-amino acid oxidases (hDAAO and yDAAO) expressed in E. coli.

RESULTS

In aqueous two-phase (PEG-phosphate) system, the S-layer:DAAO fusion proteins (shDAAO and syDAAO) were separated at the interface with a recovery of 82 ± 10.6% for shDAAO and 95 ± 1.9% for syDAAO. Some shDAAO proteins were separated as precipitates with a recovery of 41 ± 0.5% in phosphate (9%, w/w) using PEG 3000 and PEG 4000 (16%, w/w), while some syDAAO proteins were also isolated as precipitates with a recovery of 75 ± 17.5% in phosphate (9%, w/w) using PEG 4000 and PEG 8000 (16%, w/w).

CONCLUSIONS

The S-layer of L. brevis was applied to a self-assembled protein tag to enable cost-effective separation of human and yeast D-amino acid oxidases expressed in E. coli cells. Because of the self-assembling properties of S-layer proteins, human and yeast D-amino acid oxidases fused with S-layer proteins could be easily separated by aggregates at the interface and/or in a few conditions by precipitates to the bottom of the PEG-phosphate aqueous system.

Structural Analysis of the Glycine Oxidase Homologue CmiS2 Reveals a Unique Substrate Recognition Mechanism for Formation of a β-Amino Acid Starter Unit in Cremimycin Biosynthesis

The flavin adenine dinucleotide-dependent oxidase CmiS2 catalyzes the oxidation of N-carboxymethyl-3-aminononanoic acid to produce a 3-aminononanoic acid starter unit for the biosynthesis of cremimycin, a macrolactam polyketide. Although the sequence of CmiS2 is similar with that of the well-characterized glycine oxidase ThiO, the chemical structure of the substrate of CmiS2 is different from that of ThiO substrate glycine. Here, we present the biochemical and structural characterization of CmiS2. Kinetic analysis revealed that CmiS2 has a strong preference for N-carboxymethyl-3-aminononanoic acid over other substrates such as N-carboxymethyl-3-aminobutanoic acid and glycine, suggesting that CmiS2 recognizes the nonanoic acid moiety of the substrate as well as the glycine moiety. We determined the crystal structure of CmiS2 in complex with a substrate analogue, namely, S-carboxymethyl-3-thiononanoic acid, which enabled the identification of key amino acid residues involved in substrate recognition. We discovered that Asn49, Arg243, and Arg334 interact with the carboxyl group of the nonanoic acid moiety, while Pro46, Leu52, and Ile335 recognize the alkyl chain of the nonanoic acid moiety via hydrophobic interaction. These residues are highly conserved in CmiS2 homologues involved in the biosynthesis of related macrolactam polyketides but are not conserved in glycine oxidases such as ThiO. These results suggest that CmiS2-type enzymes employ a distinct mechanism of substrate recognition for the synthesis of β-amino acids.