MP Biomedicals™ β-Ncotinamide Adenine Dinucleotide Reduced, Disodium Salt

Description

• Applications: β-Nicotinamide adenine dinucleotide (NAD+) and β-Nicotinamide adenine dinucleotide, reduced (NADH) comprise a coenzyme redox pair (NAD+:NADH) involved in a wide range of enzyme catalyzed oxidation reduction reactions
• In addition to its redox function, NAD+/NADH is a donor of ADP-ribose units in ADP-ribosylaton (ADP-ribosyltransferases; poly(ADP-ribose) polymerases ) reactions and a precursor of cyclic ADP-ribose (ADP-ribosyl cyclases)
• Many metabolites and enzymes of biological interest are present in tissues at low concentrations
• With the use of β-NADH as a cofactor and several enzymes in a multistep system, known as enzyme cycling, much greater sensitivity for detection of these components is achieved
• β-NADH is fluorescent; whereas, β-NAD+ is not
• This difference in fluorescence provides a sensitive fluorescent measurement of the oxidized or reduced pyridine nucleotides at concentrations down to 10−7 M
• Discussion of optimizing the fluorescence intensity and identification of interfering substances has been reported
• Product Description: β-NADH, a pyridine nucleotide and biologically active form of nicotinic acid, is a coenzyme necessary for the catalytic reaction of certain enzymes
• β-NAD+ is a carrier for hydride ion, forming β-NADH
• The hydride ion is enzymatically removed from a substrate molecule by the action of dehydrogenases such as, malic dehydrogenase and lactic dehydrogenase
• These enzymes catalyze the reversible transfer of a hydride ion from malate or lactate to β-NAD+, forming the reduced product, β-NADH
• Unlike β-NAD+, which has no absorbance at 340 nm, β-NADH absorbs at 340 nm
• The increase in absorbance (with the formation of β-NADH) or the decrease in absorbance (with the formation β-NAD+) is the basis for measurement of activity of many enzymes at 340 nm
• Biochem/physiol Actions: NADH is a coenzyme that functions as a regenerating electron donor in catabolic processes including glycolysis, beta-oxidation and the citric acid cycle (Krebs cycle, TCA cycle)
• It participates in cell signaling events as well, for example as a substrate for the poly (ADP-ribose) polymerases (PARPs) during the DNA damage response
• The NAD+/NADH dependent sirtuins play key roles in stress responses during events involving energy metabolism, with implications in cancer biology, diabetes and neurodegenerative disease
• As a reagent, NADH can be used in enzyme cycling assays to amplify detection of activity of biologically relevant enzymes or metabolites present in low concentrations.