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| Catalog | Product Name | EC No. | CAS No. | Source | Price |
|---|---|---|---|---|---|
| NATE-0785 | β-Nicotinamide-Adenine Dinucleotide, Oxidized Form (NAD) | 53-84-9 | Inquiry |
β-Nicotinamide adenine dinucleotide (β-NAD) is a prominent biomolecule prominently found in every living cell and involved in various cellular processes. β-NAD is one of the variants of Nicotinamide Adenine Dinucleotide (NAD), a coenzyme centrally involved in redox reactions. Aside from the all-important energy metabolism, contributing to the breakdown of glucose and fatty acids, β-NAD also performs unique functions due to the β- configuration.
At the core of β-NAD lies a dinucleotide structure composed of two nucleotides, nicotinamide and adenosine diphosphate (ADP), interconnected by phosphate groups. This unique structure enables β-NAD to participate in an array of biochemical reactions, serving as a versatile mediator in cellular metabolism pathways.
β-NAD functions in redox reactions where it acts as an electron carrier. Its integral role in the glycolysis, citric acid cycle, and oxidative phosphorylation directly ties it with energy production. In its oxidized form (NAD+), it accepts electrons and is reduced to NADH. The NADH then donates these electrons in the mitochondrial electron transport chain, generating ATP.
Another critical function of β-NAD is facilitating post-translational modifications, especially ADP-ribosylation. Here, it contributes to protein function regulation, a crucial process for overall cellular homeostasis.
The metabolic fate of β-NAD predominantly revolves around the transferring of electrons during the metabolic reactions. Generally, it alternates between its oxidized (NAD+) and reduced (NADH) forms. The oxidized form accepts an electron (becoming reduced to NADH), which can be passed onto other molecules in subsequent reactions, leading to ATP production.
β-NAD finds applications in various lab-based and industrial biotechnological processes. In labs, β-NAD quantification serves as a useful tool to study the cellular systems. Measuring NAD+/NADH ratio is a popular method to determine the cell's metabolic state. Industrial processes like lactate fermentation employ bacterial strains engineered to raise their intracellular NADH levels, improving the yield. Recently, β-NAD’s role as a substrate for non-redox enzymes like sirtuins, PARPs, and CD38 has also opened up new therapeutic avenues.
Recent studies have showcased the significance of β-NAD in modulating cellular senescence and promoting longevity. The decline of β-NAD levels with age has been linked to various age-related pathologies, sparking interest in therapeutic interventions that bolster β-NAD levels to mitigate aging-associated decline.
β-NAD serves as a co-substrate for enzymes involved in DNA repair mechanisms, playing a crucial role in maintaining genomic integrity and safeguarding cells against DNA damage. Dysregulation of β-NAD levels can compromise DNA repair processes, potentially leading to genomic instability and increased susceptibility to diseases like cancer.
The clinical significance of β-NAD has emerged prominently in recent years. Its role as a substrate for sirtuins has tied it to aging and age-associated pathologies. Dysregulated NAD+ metabolism, due to lifestyle, diet or disease, can result in systemic NAD+ deficiency, leading to metabolic complications, neurodegeneration, and accelerated aging.
Restoring NAD+ levels using precursors (Nicotinamide Riboside, Nicotinamide Mononucleotide) has yielded promising results in improving metabolic health, countering neurodegeneration, and extending lifespan in preclinical models.
In summary, β-NAD, a cellular dynamo, is fundamental to life as an integral player in cellular metabolism and redox homeostasis. From a humble electron carrier to a difference-maker in aging and related diseases, β-NAD's significance transcends cellular boundaries. With continuous exploration into β-NAD biology, we can expect more innovative therapeutic and biotechnological applications in the future. The forthcoming research holds promise not only in the sphere of basic cell biology but also in the preventive and therapeutic aspects of human pathology. It emphasizes the need to persist in the evaluation of the exciting dynamics of β-NAD.
