Martino L. di Salvo

Structure and properties of recombinant human pyridoxine 5'-phosphate oxidase

Pyridoxine 5′‐phosphate oxidase catalyzes the terminal step in the synthesis of pyridoxal 5′‐phosphate. The cDNA for the human enzyme has been cloned and expressed in Escherichia coli. The purified human enzyme is a homodimer that exhibits a low catalytic rate constant of ∼0.2 sec−1 and Km values in the low micromolar range for both pyridoxine 5′phosphate and pyridoxamine 5′‐phosphate. Pyridoxal 5′‐phosphate is an effective product inhibitor. The three‐dimensional fold of the human enzyme is very similar to those of the E. coli and yeast enzymes. The human and E. coli enzymes share 39% sequence identity, but the binding sites for the tightly bound FMN and substrate are highly conserved. As observed with the E. coli enzyme, the human enzyme binds one molecule of pyridoxal 5′‐phosphate tightly on each subunit.

Glycine consumption and mitochondrial serine hydroxymethyltransferase in cancer cells: The heme connection

It was recently discovered that glycine consumption is strongly related to the rate of proliferation across cancer cells. This is very intriguing and raises the question of what is the actual role of this amino acid in cancer metabolism. Cancer cells are greedy for glycine. In particular, the mitochondrial production of glycine seems to be utterly important. Overexpression of mitochondrial serine hydroxymethyltransferase, the enzyme converting l-serine to glycine, assures an adequate supply of glycine to rapidly proliferating cancer cells. In fact, silencing of mitochondrial serine hydroxymethyltransferase was shown to halt cancer cell proliferation. Direct incorporation of glycine carbon atoms into the purine ring has been proposed to be one main reason for the importance of glycine in cancer cell metabolism. We believe that, as far as the importance of glycine in cancer is concerned, a central role of this amino acid, namely its participation to heme biosynthesis, has been neglected. In mitochondria, glycine condenses with succinyl-CoA to form 5-aminolevulinate, the universal precursor of the different forms of heme contained in cytochromes and oxidative phosphorylation complexes. Our hypothesis is that mitochondrial serine hydroxymethyltransferase is fundamental to sustain cancer metabolism since production of glycine fuels heme biosynthesis and therefore oxidative phosphorylation. Respiration of cancer cells may then ultimately rely on endogenous glycine synthesis by mitochondrial serine hydroxymethyltransferase. The link between mitochondrial serine hydroxymethyltransferase activity and heme biosynthesis represents an important and still unexplored aspect of the whole picture of cancer cell metabolism. Our hypothesis might be tested using a combination of metabolic tracing and gene silencing on different cancer cell lines. The experiments should be devised so as to assess the importance of mitochondrial serine hydroxymethyltransferase and the glycine deriving from its reaction as a precursor of heme. If the observed increase of glycine consumption in rapidly proliferating cancer cells has its basis in the need for heme biosynthesis, then mitochondrial serine hydroxymethyltransferase should be considered as a key target for the development of new chemotherapeutic agents.

Crystal structure of human pyridoxal kinase: Structural basis of M + and M2+ activation

Pyridoxal kinase catalyzes the transfer of a phosphate group from ATP to the 5′ alcohol of pyridoxine, pyridoxamine, and pyridoxal. In this work, kinetic studies were conducted to examine monovalent cation dependence of human pyridoxal kinase kinetic parameters. The results show that hPLK affinity for ATP and PL is increased manyfold in the presence of K+ when compared to Na+; however, the maximal activity of the Na+ form of the enzyme is more than double the activity in the presence of K+. Other monovalent cations, Li+, Cs+, and Rb+ do not show significant activity. We have determined the crystal structure of hPLK in the unliganded form, and in complex with MgATP to 2.0 and 2.2 Å resolution, respectively. Overall, the two structures show similar open conformation, and likely represent the catalytically idle state. The crystal structure of the MgATP complex also reveals Mg2+ and Na+ acting in tandem to anchor the ATP at the active site. Interestingly, the active site of hPLK acts as a sink to bind several molecules of MPD. The features of monovalent and divalent metal cation binding, active site structure, and vitamin B6 specificity are discussed in terms of the kinetic and structural studies, and are compared with those of the sheep and Escherichia coli enzymes.

Coupling Bioorthogonal Chemistries with Artificial Metabolism: Intracellular Biosynthesis of Azidohomoalanine and Its Incorporation into Recombinant Proteins

In this paper, we present a novel, “single experiment” methodology based on genetic engineering of metabolic pathways for direct intracellular production of non-canonical amino acids from simple precursors, coupled with expanded genetic code. In particular, we engineered the intracellular biosynthesis of l-azidohomoalanine from O-acetyl-l-homoserine and NaN3, and achieved its direct incorporation into recombinant target proteins by AUG codon reassignment in a methionine-auxotroph E. coli strain. In our system, the host’s methionine biosynthetic pathway was first diverted towards the production of the desired non-canonical amino acid by exploiting the broad reaction specificity of recombinant pyridoxal phosphate-dependent O-acetylhomoserine sulfhydrylase from Corynebacterium glutamicum. Then, the expression of the target protein barstar, accompanied with efficient l-azidohomoalanine incorporation in place of l-methionine, was accomplished. This work stands as proof-of-principle and paves the way for additional work towards intracellular production and site-specific incorporation of biotechnologically relevant non-canonical amino acids directly from common fermentable sources.

Molecular Basis of Reduced Pyridoxine 5′-Phosphate Oxidase Catalytic Activity in Neonatal Epileptic Encephalopathy Disorder

Mutations in pyridoxine 5′-phosphate oxidase are known to cause neonatal epileptic encephalopathy. This disorder has no cure or effective treatment and is often fatal. Pyridoxine 5′-phosphate oxidase catalyzes the oxidation of pyridoxine 5′-phosphate to pyridoxal 5′-phosphate, the active cofactor form of vitamin B6 required by more than 140 different catalytic activities, including enzymes involved in amino acid metabolism and biosynthesis of neurotransmitters. Our aim is to elucidate the mechanism by which a homozygous missense mutation (R229W) in the oxidase, linked to neonatal epileptic encephalopathy, leads to reduced oxidase activity. The R229W variant is ∼850-fold less efficient than the wild-type enzyme due to an ∼192-fold decrease in pyridoxine 5′-phosphate affinity and an ∼4.5-fold decrease in catalytic activity. There is also an ∼50-fold reduction in the affinity of the R229W variant for the FMN cofactor. A 2.5 Å crystal structure of the R229W variant shows that the substitution of Arg-229 at the FMN binding site has led to a loss of hydrogen-bond and/or salt-bridge interactions between FMN and Arg-229 and Ser-175. Additionally, the mutation has led to an alteration of the configuration of a β-strand-loop-β-strand structure at the active site, resulting in loss of two critical hydrogen-bond interactions involving residues His-227 and Arg-225, which are important for substrate binding and orientation for catalysis. These results provide a molecular basis for the phenotype associated with the R229W mutation, as well as providing a foundation for understanding the pathophysiological consequences of pyridoxine 5′-phosphate oxidase mutations.

Molecular mechanisms of the non-coenzyme action of thiamin in brain: biochemical, structural and pathway analysis

Thiamin (vitamin B1) is a pharmacological agent boosting central metabolism through the action of the coenzyme thiamin diphosphate (ThDP). However, positive effects, including improved cognition, of high thiamin doses in neurodegeneration may be observed without increased ThDP or ThDP-dependent enzymes in brain. Here, we determine protein partners and metabolic pathways where thiamin acts beyond its coenzyme role. Malate dehydrogenase, glutamate dehydrogenase and pyridoxal kinase were identified as abundant proteins binding to thiamin- or thiazolium-modified sorbents. Kinetic studies, supported by structural analysis, revealed allosteric regulation of these proteins by thiamin and/or its derivatives. Thiamin triphosphate and adenylated thiamin triphosphate activate glutamate dehydrogenase. Thiamin and ThDP regulate malate dehydrogenase isoforms and pyridoxal kinase. Thiamin regulation of enzymes related to malate-aspartate shuttle may impact on malate/citrate exchange, responsible for exporting acetyl residues from mitochondria. Indeed, bioinformatic analyses found an association between thiamin- and thiazolium-binding proteins and the term acetylation. Our interdisciplinary study shows that thiamin is not only a coenzyme for acetyl-CoA production, but also an allosteric regulator of acetyl-CoA metabolism including regulatory acetylation of proteins and acetylcholine biosynthesis. Moreover, thiamin action in neurodegeneration may also involve neurodegeneration-related 14-3-3, DJ-1 and β-amyloid precursor proteins identified among the thiamin- and/or thiazolium-binding proteins.

Pyridoxal 5′-Phosphate Is a Slow Tight Binding Inhibitor of E. coli Pyridoxal Kinase

Pyridoxal 5′-phosphate (PLP) is a cofactor for dozens of B6 requiring enzymes. PLP reacts with apo-B6 enzymes by forming an aldimine linkage with the ε-amino group of an active site lysine residue, thus yielding the catalytically active holo-B6 enzyme. During protein turnover, the PLP is salvaged by first converting it to pyridoxal by a phosphatase and then back to PLP by pyridoxal kinase. Nonetheless, PLP poses a potential toxicity problem for the cell since its reactive 4′-aldehyde moiety forms covalent adducts with other compounds and non-B6 proteins containing thiol or amino groups. The regulation of PLP homeostasis in the cell is thus an important, yet unresolved issue. In this report, using site-directed mutagenesis, kinetic, spectroscopic and chromatographic studies we show that pyridoxal kinase from E. coli forms a complex with the product PLP to form an inactive enzyme complex. Evidence is presented that, in the inhibited complex, PLP has formed an aldimine bond with an active site lysine residue during catalytic turnover. The rate of dissociation of PLP from the complex is very slow, being only partially released after a 2-hour incubation with PLP phosphatase. Interestingly, the inactive pyridoxal kinase•PLP complex can be partially reactivated by transferring the tightly bound PLP to an apo-B6 enzyme. These results open new perspectives on the mechanism of regulation and role of pyridoxal kinase in the Escherichia coli cell.

On the catalytic mechanism and stereospecificity of Escherichia coli l-threonine aldolase.

l‐Threonine aldolases (l‐TAs) represent a family of homologous pyridoxal 5′‐phosphate‐dependent enzymes found in bacteria and fungi, and catalyse the reversible cleavage of several l‐3‐hydroxy‐α‐amino acids. l‐TAs have great biotechnological potential, as they catalyse the formation of carbon–carbon bonds, and therefore may be exploited for the bioorganic synthesis of l‐3‐hydroxyamino acids that are biologically active or constitute building blocks for pharmaceutical molecules. Many l‐TAs, showing different stereospecificity towards the Cβ configuration, have been isolated. Because of their potential to carry out diastereoselective syntheses, l‐TAs have been subjected to structural, functional and mechanistic studies. Nevertheless, their catalytic mechanism and the structural bases of their stereospecificity have not been elucidated. In this study, we have determined the crystal structure of low‐specificity l‐TA from Escherichia coli at 2.2‐Å resolution, in the unliganded form and cocrystallized with l‐serine and l‐threonine. Furthermore, several active site mutants have been functionally characterized in order to elucidate the reaction mechanism and the molecular bases of stereospecificity. No active site catalytic residue was revealed, and a structural water molecule was assumed to act as the catalytic base in the retro‐aldol cleavage reaction. Interestingly, the very large active site opening of E. coli l‐TA suggests that much larger molecules than l‐threonine isomers may be easily accommodated, and l‐TAs may actually have diverse physiological functions in different organisms. Substrate recognition and reaction specificity seem to be guided by the overall microenvironment that surrounds the substrate at the enzyme active site, rather than by one ore more specific residues.

Molecular mechanism of PdxR – a transcriptional activator involved in the regulation of vitamin B6 biosynthesis in the probiotic bacterium Bacillus clausii

Pyridoxal 5′‐phosphate (PLP), the well‐known active form of vitamin B6, is an essential enzyme cofactor involved in a large number of metabolic processes. PLP levels need to be finely tuned in response to cell requirements; however, little is known about the regulation of PLP biosynthesis and recycling pathways. The transcriptional regulator PdxR activates transcription of the pdxST genes encoding PLP synthase. It is characterized by an N‐terminal helix‐turn‐helix motif that binds DNA and an effector‐binding C‐terminal domain homologous to PLP‐dependent enzymes. Although it is known that PLP acts as an anti‐activator, the mechanism of action of PdxR is unknown. In the present study, we analyzed the biochemical and DNA‐binding properties of PdxR from the probiotic Bacillus clausii. Spectroscopic measurements showed that PLP is the only B6 vitamer that acts as an effector molecule of PdxR. Binding of PLP to PdxR determines a protein conformational change, as detected by gel filtration chromatography and limited proteolysis experiments. We showed that two direct repeats and one inverted repeat are present in the DNA promoter region and PdxR is able to bind DNA fragments containing any combination of two of them. However, when PLP binds to PdxR, it modifies the DNA‐binding properties of the protein, making it selective for inverted repeats. A molecular mechanism is proposed in which the two different DNA binding modalities of PdxR determined by the presence or absence of PLP are responsible for the control of pdxST transcription.

How pyridoxal 5′‐phosphate differentially regulates human cytosolic and mitochondrial serine hydroxymethyltransferase oligomeric state

Adaptive metabolic reprogramming gives cancer cells a proliferative advantage. Tumour cells extensively use glycolysis to sustain anabolism and produce serine, which not only refuels the one‐carbon units necessary for the synthesis of nucleotide precursors and for DNA methylation, but also affects the cellular redox homeostasis. Given its central role in serine metabolism, serine hydroxymethyltransferase (SHMT), a pyridoxal 5′‐phosphate (PLP)‐dependent enzyme, is an attractive target for tumour chemotherapy. In humans, the cytosolic isoform (SHMT1) and the mitochondrial isoform (SHMT2) have distinct cellular roles, but high sequence identity and comparable catalytic properties, which may complicate development of successful therapeutic strategies. Here, we investigated how binding of the cofactor PLP controls the oligomeric state of the human isoforms. The fact that eukaryotic SHMTs are tetrameric proteins while bacterial SHMTs function as dimers may suggest that the quaternary assembly in eukaryotes provides an advantage to fine‐tune SHMT function and differentially regulate intertwined metabolic fluxes, and may provide a tool to address the specificity problem. We determined the crystal structure of SHMT2, and compared it to the apo‐enzyme structure, showing that PLP binding triggers a disorder‐to‐order transition accompanied by a large rigid‐body movement of the two cofactor‐binding domains. Moreover, we demonstrated that SHMT1 exists in solution as a tetramer, both in the absence and presence of PLP, while SHMT2 undergoes a dimer‐to‐tetramer transition upon PLP binding. These findings indicate an unexpected structural difference between the two human SHMT isoforms, which opens new perspectives for understanding their differing behaviours, roles or regulation mechanisms in response to PLP availability in vivo.