Nicotinamide adenine dinucleotide phosphate, abbreviated NADP or, in older notation, TPN (triphosphopyridine nucleotide), is a cofactor used in anabolic reactions, such as the Calvin cycle and lipid and nucleic acid syntheses, which require it as a reducing agent ('hydrogen source'). NADPH is the reduced form, whereas NADP is the oxidized form. NADP is used by all forms of cellular life. NADP is essential for life because it is needed for cellular respiration.
NADP differs from NAD by the presence of an additional phosphate group on the 2' position of the ribose ring that carries the adenine moiety. This extra phosphate is added by NAD<sup>+</sup> kinase and removed by NADP<sup>+</sup> phosphatase.
Biosynthesis
NADP
In general, NADP<sup>+</sup> is synthesized before NADPH is. Such a reaction usually starts with NAD<sup>+</sup> from either the de-novo or the salvage pathway, with NAD<sup>+</sup> kinase adding the extra phosphate group. ADP-ribosyl cyclase allows for synthesis from nicotinamide in the salvage pathway, and NADP<sup>+</sup> phosphatase can convert NADPH back to NADH to maintain a balance. The prokaryotic pathway is less well understood, but with all the similar proteins the process should work in a similar way. The isocitrate dehydrogenase mechanism appears to be the major source of NADPH in fat and possibly also liver cells. These processes are also found in bacteria. Bacteria can also use a NADP-dependent glyceraldehyde 3-phosphate dehydrogenase for the same purpose. Like the pentose phosphate pathway, these pathways are related to parts of glycolysis.
NADPH can also be generated through pathways unrelated to carbon metabolism. The ferredoxin reductase is such an example. Nicotinamide nucleotide transhydrogenase transfers the hydrogen between NAD(P)H and NAD(P)<sup>+</sup>, and is found in eukaryotic mitochondria and many bacteria. There are versions that depend on a proton gradient to work and ones that do not. Some anaerobic organisms use NADP<sup>+</sup>-linked hydrogenase, ripping a hydride from hydrogen gas to produce a proton and NADPH.
Function
NADPH provides the reducing agents, usually hydrogen atoms, for biosynthetic reactions and the oxidation-reduction involved in protecting against the toxicity of reactive oxygen species (ROS), allowing the regeneration of glutathione (GSH). NADPH is also used for anabolic pathways, such as cholesterol synthesis, steroid synthesis, ascorbic acid synthesis,
It is the source of reducing equivalents for cytochrome P450 hydroxylation of aromatic compounds, steroids, alcohols, and drugs.
Stability
NADH and NADPH are very stable in basic solutions, but NAD<sup>+</sup> and NADP<sup>+</sup> are degraded in basic solutions into a fluorescent product that can be used conveniently for quantitation. Conversely, NADPH and NADH are degraded by acidic solutions while NAD<sup>+</sup>/NADP<sup>+</sup> are fairly stable to acid.
Enzymes that use NADP(H) as a coenzyme
Many enzymes that bind NADP share a common super-secondary structure named the "Rossmann fold". The initial beta-alpha-beta (βαβ) fold is the most conserved segment of the Rossmann folds. This segment is in contact with the ADP portion of NADP. Therefore, it is also called an "ADP-binding βαβ fold".
- Adrenodoxin reductase: This enzyme is present ubiquitously in most organisms. It transfers two electrons from NADPH to FAD. In vertebrates, it serves as the first enzyme in the chain of mitochondrial P450 systems that synthesize steroid hormones.
Enzymes that use NADP(H) as a substrate
In 2018 and 2019, the first two reports of enzymes that catalyze the removal of the 2' phosphate of NADP(H) in eukaryotes emerged. First the cytoplasmic protein MESH1 (), then the mitochondrial protein nocturnin were reported. Of note, the structures and NADPH binding of MESH1 (5VXA) and nocturnin (6NF0) are not related.