Entity Detail — Knowledge Graph Node
This page aggregates everything SciDEX knows about NAD: its mechanistic relationships (Knowledge Graph edges), hypotheses targeting it, analyses mentioning it, and supporting scientific papers. The interactive graph below shows its immediate neighbors. All content is AI-synthesized from peer-reviewed literature.
NAD is a concept in neurodegeneration research. Key relationships include: activates, regulates, associated with. Associated with AD, ADH, ALI. Connected to 546 entities in the SciDEX knowledge graph.
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| Name | NAD |
| Key Genes/Proteins | ABCA7, ACC, Actin, Adiponectin, ADORA2B, AGING |
| Related Diseases | AD, Addiction, ADH, aging, Aging |
| Linked Hypotheses | 16 hypotheses |
Knowledge base pages for this entity
graph TD
NAD["NAD"]
NAD -->|"regulates"| neuronal_bioenergetics["neuronal bioenergetics"]
NAD -->|"regulates"| oxidative_stress["oxidative stress"]
NAD -->|"regulates"| epigenetic_changes["epigenetic changes"]
NAD -->|"regulates"| Tumor["Tumor"]
NAD -->|"regulates"| Neurodegeneration["Neurodegeneration"]
NAD -->|"regulates"| Cancer["Cancer"]
NAD -->|"regulates"| Autoimmune["Autoimmune"]
NAD -->|"activates"| Aging["Aging"]
NAD -->|"regulates"| Cardiovascular["Cardiovascular"]
NAD -->|"causes"| Inflammation["Inflammation"]
cd38["cd38"] -->|"regulates"| NAD
P7C3_A20["P7C3-A20"] -->|"activates"| NAD
ATP["ATP"] -->|"causes"| NAD
CD38["CD38"] -->|"regulates"| NAD
CIRCADIAN_RHYTHM["CIRCADIAN RHYTHM"] -->|"regulates"| NAD
DNA["DNA"] -->|"contributes to"| NAD
SIRT6["SIRT6"] -->|"inhibits"| NAD
EGR2["EGR2"] -->|"inhibits"| NAD
PARP1["PARP1"] -->|"inhibits"| NAD| Target | Relation | Type | Str |
|---|---|---|---|
| SIRT1 | regulates | gene | 1.00 |
| Aging | regulates | disease | 1.00 |
| Inflammation | activates | disease | 1.00 |
| Als | activates | disease | 1.00 |
| MITOCHONDRIA | activates | gene | 1.00 |
| Als | regulates | disease | 1.00 |
| SIRT1 | associated_with | gene | 1.00 |
| Aging | activates | disease | 1.00 |
| AGING | activates | gene | 1.00 |
| SIRT1 | activates | gene | 1.00 |
| AGING | regulates | gene | 1.00 |
| Neurodegeneration | activates | disease | 0.95 |
| Cancer | activates | disease | 0.95 |
| Inflammation | regulates | disease | 0.95 |
| Cancer | regulates | disease | 0.95 |
| DNA Repair | involved_in | process | 0.95 |
| Redox Metabolism | involved_in | process | 0.95 |
| Energy Metabolism | involved_in | process | 0.95 |
| Obesity | activates | disease | 0.95 |
| Aging | associated_with | phenotype | 0.90 |
| Immune Response | involved_in | process | 0.90 |
| aging | activates | disease | 0.90 |
| aging | associated_with | disease | 0.90 |
| NAMPT | associated_with | gene | 0.90 |
| SIRT3 | activates | protein | 0.90 |
| NEURODEGENERATION | activates | gene | 0.90 |
| APOPTOSIS | therapeutic_target | gene | 0.90 |
| NEURODEGENERATIVE DISEASES | activates | gene | 0.90 |
| Apoptosis | therapeutic_target | pathway | 0.90 |
| OXIDATIVE STRESS | activates | gene | 0.90 |
| Oxidative Phosphorylation | activates | pathway | 0.90 |
| AMPK | activates | gene | 0.90 |
| INFLAMMATION | activates | gene | 0.90 |
| CANCER | activates | gene | 0.90 |
| Oxidative Stress | activates | pathway | 0.90 |
| MITOCHONDRIAL DYSFUNCTION | activates | gene | 0.90 |
| Glycolysis | activates | pathway | 0.90 |
| CANCER | regulates | gene | 0.90 |
| Mtor | activates | pathway | 0.90 |
| Cancer | associated_with | disease | 0.85 |
| Diabetes | activates | disease | 0.85 |
| Aging | associated_with | disease | 0.85 |
| DAM microglia | expressed_in | cell_type | 0.85 |
| NAD+ metabolism | participates_in | pathway | 0.85 |
| Senescence | therapeutic_target | disease | 0.85 |
| Inflammation | therapeutic_target | disease | 0.85 |
| Parkinson | activates | disease | 0.85 |
| Tumor | regulates | disease | 0.85 |
| Alzheimer | activates | disease | 0.85 |
| Neuroprotection | mediates | process | 0.80 |
| Source | Relation | Type | Str |
|---|---|---|---|
| nicotinamide | targets | drug | 0.85 |
| Dietary Restriction | modulates | process | 0.85 |
| CD38 | catalyzes | protein | 0.85 |
| CD38 | regulates | gene | 0.85 |
| cd38 | regulates | gene | 0.85 |
| CD38 | associated_with | gene | 0.70 |
| AGING | associated_with | gene | 0.70 |
| DNA | disrupts | gene | 0.70 |
| P7C3-A20 | activates | drug | 0.70 |
| ATP | associated_with | gene | 0.70 |
| MONOCYTE | activates | cell_type | 0.65 |
| AMPK | activates | gene | 0.65 |
| MTOR | regulates | gene | 0.65 |
| ENDOTHELIAL | regulates | cell_type | 0.65 |
| APP | inhibits | gene | 0.65 |
| ALZHEIMER'S DISEASE | associated_with | disease | 0.65 |
| ATP | regulates | gene | 0.65 |
| CANCER | interacts_with | disease | 0.65 |
| BMAL1 | activates | gene | 0.65 |
| MACROPHAGE | activates | cell_type | 0.65 |
| CLOCK | activates | gene | 0.65 |
| CD38 | protects_against | gene | 0.60 |
| DNA | associated_with | gene | 0.60 |
| PTEN | therapeutic_target | gene | 0.60 |
| SIRT4 | expressed_in | gene | 0.60 |
| SIRT6 | expressed_in | gene | 0.60 |
| SIRT6 | activates | gene | 0.60 |
| CLOCK | regulates | gene | 0.60 |
| NAMPT | interacts_with | gene | 0.60 |
| NADH | phosphorylates | gene | 0.60 |
| NAMPT | inhibits | gene | 0.60 |
| ALZHEIMER | therapeutic_target | gene | 0.60 |
| NLRP12 | interacts_with | gene | 0.60 |
| TLR | associated_with | gene | 0.60 |
| GSH | treats | gene | 0.60 |
| NEURODEGENERATION | associated_with | gene | 0.60 |
| SIRT1 | activates | gene | 0.60 |
| BRAIN INJURY | regulates | gene | 0.60 |
| BAX | activates | gene | 0.60 |
| AGING | therapeutic_target | gene | 0.60 |
| OVERVIEW | therapeutic_target | gene | 0.60 |
| AGING | inhibits | gene | 0.60 |
| GPX4 | regulates | gene | 0.60 |
| OXIDATIVE STRESS | therapeutic_target | gene | 0.60 |
| DEMENTIA | regulates | gene | 0.60 |
| INFLAMMATION | therapeutic_target | gene | 0.60 |
| INFLAMMATION | regulates | gene | 0.60 |
| OVERVIEW | regulates | gene | 0.60 |
| EXERCISE | regulates | gene | 0.60 |
| PRKN | regulates | gene | 0.60 |
Hypotheses where this entity is a therapeutic target
Scientific analyses that reference this entity
neurodegeneration | 2026-04-16 | 2 hypotheses Top: 0.616
neurodegeneration | 2026-04-04 | 0 hypotheses
Experimental studies targeting or related to this entity
| Experiment | Type | Disease | Score | Feasibility | Model | Status | Est. Cost |
|---|---|---|---|---|---|---|---|
| Sirtuin Pathway Dysfunction Validation in Parkinson's Disease | clinical | Parkinson's Disease | 0.400 | 0.50 | human | proposed | $6,550,000 |
| Mechanism: Why Does Amyloid Removal Only Slow Decline 27%? | clinical | Alzheimer's Disease | 0.400 | 0.50 | human | proposed | $7,500,000 |
| Microglial Aging and Immune Memory in Neurodegeneration — Training the | validation | Alzheimer's Disease | 0.400 | 0.50 | human | proposed | $2,960,000 |
| Normal Aging to Alzheimer's Disease Transition Trigger — Identifying t | validation | Alzheimer's Disease | 0.400 | 0.50 | human | proposed | $2,280,000 |
| Peroxisomal Dysfunction Validation in Parkinson's Disease | validation | Parkinson's Disease | 0.400 | 0.50 | human | proposed | $2,280,000 |
| Senolytic Therapy (D+Q) Phase IIa Trial in Early Alzheimer's Disease | clinical | Alzheimer's Disease | 0.400 | 0.50 | human | proposed | $5,460,000 |
| Sirtuin Dysfunction Validation in Parkinson's Disease | clinical | Parkinson's Disease | 0.400 | 0.50 | human | proposed | $6,550,000 |
Scientific publications cited in analyses involving this entity
| Title & PMID | Authors | Journal | Year | Citations |
|---|---|---|---|---|
| Channeling Nicotinamide Phosphoribosyltransferase (NAMPT) to Address Life and De [PMID:38580317] | Velma GR, Krider IS, Alves ETM, Courey J | J Med Chem | 2024 | 1 |
| SIRT6-regulated macrophage efferocytosis epigenetically controls inflammation re [PMID:36593966] | Li B, Xin Z, Gao S, Li Y, Guo S, Fu Y, X | Theranostics | 2023 | 1 |
| Assessing the Status of Mandatory Tuberculosis Case Notification among Private P [PMID:35068738] | Duggal K, Elsy M, Majella MG, Akkilagunt | Indian J Community Med | 2021 | 1 |
| Nicotinamide mononucleotide increases muscle insulin sensitivity in prediabetic [PMID:33888596] | Yoshino M, Yoshino J, Kayser BD, Patti G | Science | 2021 | 1 |
| NAD(+) metabolism, stemness, the immune response, and cancer. [PMID:33384409] | Navas LE, Carnero A | Signal Transduct Target Ther | 2021 | 1 |
| Protocol for the Bottom-Up Proteomic Analysis of Mouse Spleen. [PMID:33377090] | Dowling P, Gargan S, Zweyer M, Henry M, | STAR Protoc | 2020 | 1 |
| Dynamic Acetylation of Phosphoenolpyruvate Carboxykinase Toggles Enzyme Activity [PMID:30193097] | Latorre-Muro P, Baeza J, Armstrong EA, H | Mol Cell | 2018 | 1 |
| NAD metabolism fuels human and mouse intestinal inflammation. [PMID:28877980] | Gerner RR, Klepsch V, Macheiner S, Arnha | Gut | 2018 | 1 |
| The SWI/SNF Protein PBRM1 Restrains VHL-Loss-Driven Clear Cell Renal Cell Carcin [PMID:28329682] | Nargund AM, Pham CG, Dong Y, Wang PI, Os | Cell Rep | 2017 | 1 |
| Mitochondrial Dysfunction Induces Senescence with a Distinct Secretory Phenotype [PMID:26686024] | Wiley CD, Velarde MC, Lecot P, Liu S, Sa | Cell Metab | 2016 | 1 |
| NAD+ and sirtuins in aging and disease. [PMID:24786309] | Imai S, Guarente L | Trends Cell Biol | 2014 | 1 |
| Mitochondrial NAD(+)-mediated mitophagy alleviates type I interferon response to [PMID:41231107] | Lan T, Shang D, Lin L, Wang H, Zou J et | Autophagy | 2026 | 0 |
| SIRT6 inhibits intermittent hypoxia-induced lung injury by stabilizing NRF2. [PMID:41478020] | Qin R, Liu Z, Li R, Li Y, Yang Y et al. | Tissue Cell | 2026 | 0 |
| cGAS-STING signaling in Alzheimer's disease: Microglial mechanisms and therapeut [PMID:41481960] | Fazal F, Dar NJ, Ahamad S, Khan S, Bano | Mol Aspects Med | 2026 | 0 |
| Opportunities and challenges of targeting cGAS-STING in cancer. [PMID:41486397] | Lu C, Wang W, Fu YX | Nat Rev Cancer | 2026 | 0 |
| CircZBTB44-Encoded Peptide ZBTB44-342aa Alleviates Aortic Valve Calcification Vi [PMID:41487094] | Hu D, Lin Y, Huang H, Xian G, Chen Y et | Circ Res | 2026 | 0 |
| Inhibiting macrophage-derived lactate transport restores cGAS-STING signalling a [PMID:41495200] | Li D, Cui G, Yang K, Lu C, Jiang Y et al | Nat Cell Biol | 2026 | 0 |
| cGAS-STING activation in Parkinson's Disease: From mechanisms to Disease-Modifyi [PMID:41500413] | Solomon J, Mandal S, Aran KR | Gene | 2026 | 0 |
| Ubiquitination-directed cytosolic DNA degradation governs cGAS-STING-mediated im [PMID:41512867] | Li L, Ye Q, Ma J, Wang Z, Liu T et al. | Cancer Cell | 2026 | 0 |
| Inflammation-targeted single-atom nanozymes drive microglial depolarization and [PMID:41624511] | Liu B, Xiang C, Zhang X, Guo W, Wu H et | Mater Today Bio | 2026 | 0 |
Multi-agent debates referencing this entity
closed · Rounds: 4 · Score: 0.30 · 2026-04-21
closed · Rounds: 4 · Score: 0.95 · 2026-04-16
Hypotheses and analyses mentioning NAD in their description or question text
Score: 0.698 · neurodegeneration · 2026-04-14
## Mechanistic Overview SARM1-Mediated NAD+ Depletion as Terminal Executor of MCT1-Dependent Axon Degeneration starts fr
Score: 0.667 · neurodegeneration · 2026-04-02
## Mechanistic Overview SIRT6-NAD+ Axis Enhancement Therapy starts from the claim that modulating SIRT6 within the disea
Score: 0.639 · neurodegeneration · 2026-04-04
## Mechanistic Overview Mitochondrial NAD+ Salvage Enhancement starts from the claim that modulating STING1 within the d
Score: 0.616 · neurodegeneration · 2026-04-16
## **Molecular Mechanism and Rationale** The nicotinamide adenine dinucleotide (NAD+) biosynthetic pathway represents a
Score: 0.578 · neurodegeneration · 2026-04-21
## **Molecular Mechanism and Rationale** The NAD+/SARM1 axis represents a critical metabolic checkpoint that coordinate
Score: 0.575 · neurodegeneration · 2026-04-25
High risk. The Expert identifies a fatal flaw: CD38 is predominantly expressed in peripheral immune cells (B cells, T ce
Score: 0.520 · metabolomics · 2026-04-25
NAD+ Precursor Supplementation to Reverse Poly(ADP-ribose) Polymerase-Driven Metabolic Catastrophe