Pyridoxine 5â²-phosphate oxidase is an enzyme, encoded by the PNPO gene, that catalyzes several reactions in the vitamin B<sub>6</sub> metabolism pathway. Pyridoxine 5â²-phosphate oxidase catalyzes the final, rate-limiting step in vitamin B<sub>6</sub> metabolism, the biosynthesis of pyridoxal 5â²-phosphate, the biologically active form of vitamin B<sub>6</sub> which acts as an essential cofactor. Pyridoxine 5â²-phosphate oxidase is a member of the enzyme class oxidases, or more specifically, oxidoreductases. These enzymes catalyze a simultaneous oxidation-reduction reaction. The substrate oxidase enzymes is hydroxylated by one oxygen atom of molecular oxygen. Concurrently, the other oxygen atom is reduced to water. Even though molecular oxygen is the electron acceptor in these enzymes' reactions, they are unique because oxygen does not appear in the oxidized product.
The active form of vitamin B<sub>6</sub>, pyridoxal 5'-phosphate (PLP), is critical for normal cellular function. Some cancer cells have notable differences in vitamin B<sub>6</sub> metabolism compared to their normal counterparts. The rate-limiting enzyme in vitamin B<sub>6</sub> synthesis is pyridoxine-5'-phosphate oxidase (PNPO; EC 1.4.3.5).[supplied by OMIM]
Pyridoxine 5â²-phosphate oxidase is a homodimer, or a molecule consisting of two identical polypeptide subunits. It is hypothesized that the two monomers are held together by disulfide bonds. There are also salt-bridge interactions between the two monomers. Each subunit tightly binds one molecule of pyridoxal 5â²-phosphate. Both alpha-helices and beta-sheets are present in the protein motif, which is best described as a split-barrel structure. This structure is due, in part, to the disulfide bonds present in the secondary protein structure of this enzyme. Multiple thiol groups (âÂÂSH) indicate the presence of disulfide bonds in the structure of the molecule. This enzyme requires the presence of a cofactor, FMN (flavin mononucleotide). Cofactors are ions or coenzymes necessary for enzyme activity. The FMN is located in a deep cleft (formed by the two polypeptide subunits), and held in place by extensive hydrogen-bond interactions with the protein. In this particular case, the FMN helps the enzyme to bind the substrates. In the absence of pyridoxal 5â²-phosphate (PLP), the active site of the enzyme is in an âÂÂopenâ conformation. Once substrate binds and is converted to PLP, the active site of the enzyme is in a partially âÂÂclosedâ conformation. Specific amino acid residues can form hydrogen bonds with the PLP, thus forming a lid that physically covers the active site, giving rise to the âÂÂclosedâ conformation.
Pyridoxine 5â²-phosphate oxidase is the enzyme that catalyzes the rate-limited step of the B<sub>6</sub> metabolism pathway. Vitamin B<sub>6</sub>, which is also known as pyridoxine, is a crucial nutrient for the human body, as it is responsible for more bodily functions than any other vitamin. Vitamin B<sub>6</sub> is a coenzyme in the metabolism of carbohydrates, fats and proteins. This means that the enzymes which break these entities down for use in the body cannot function unless Vitamin B<sub>6</sub> is present to induce a conformational change in the enzyme, thus activating it. Vitamin B<sub>6</sub> also plays a role in the synthesis of hormones, red blood cells, neurotransmitters and enzymes. A person who is deficient in Vitamin B<sub>6</sub> could suffer from insomnia, as well as suffer damage to the central nervous system.
Pyridoxine 5â²-phosphate oxidase catalyzes several reactions; the two most important are the deamination of pyridoxamine 5â²-phosphate and the dehydrogenation (oxidation) of pyridoxine 5-phosphate, both of which are key intermediates in the metabolism of B<sub>6</sub>. Pyridoxine 5â²-phosphate oxidase's EC number is 1.4.3.5.
Pyridoxine 5â²-phosphate oxidase also plays a role in nitrogen metabolism, converting amines to aldehydes and NH<sub>3</sub> by the reaction:
In humans, the pyridoxine 5â²-phosphate oxidase enzyme exhibits a low catalytic rate constant of 0.2 s<sup>âÂÂ1</sup>, with low K<sub>m</sub> values for both pyridoxine 5â²-phosphate and pyridoxamine 5â²-phosphate. The enzyme also has a low turnover rate, meaning that it is relatively slow converting substrate to product. Pyridoxal 5â²-phosphate is an effective product inhibitor. Since pyridoxal 5â²-phosphate, the active form of vitamin B<sub>6</sub>, is the product of the metabolic pathway, if it exists in excess, then the pathway need not proceed to keep making product. However, if it exists in low concentrations, then that is a signal for the pathway to synthesize more. This is an example of feedback inhibition.
Pyridoxine 5â²-phosphate oxidase has been highly conserved over time, as there are many similarities between the enzyme as it is found in humans and Escherichia coli. Although there is only 39% retention of amino acid sequence from the E. coli version of the enzyme to the human version, the sequences for the FMN binding site and the substrate active sites are among the very highly conserved portion. One of the key differences is that the human pyridoxine 5â²-phosphate oxidase has a higher specificity for the pyridoxamine 5â²-phosphate substrate, whereas the pyridoxine 5â²-phosphate oxidase in E. coli has a higher specificity pyridoxal 5â²-phosphate substrate.
Mutations of the PNPO gene may result in the development of pyridoxamine 5'-phosphate oxidase deficiency, a disease presenting soon after birth with seizures and subsequent encephalopathy.