Database Query Results : Artemisinin, , Glycolysis

ART/DHA, Artemisinin: Click to Expand ⟱
Features:

Artemisinin — a plant-derived sesquiterpene lactone endoperoxide (from Artemisia annua) best known as the parent scaffold for artemisinin-class antimalarials and widely investigated as a tumor-selective redox/iron-reactive cytotoxic agent. It is a small-molecule natural product (drug-like phytochemical) whose major clinical derivatives include artesunate (water-soluble), artemether/arteether (lipophilic), and the active metabolite dihydroartemisinin (DHA). In oncology literature the abbreviation set commonly includes ART (artemisinin), AS (artesunate), and DHA (dihydroartemisinin); many mechanistic claims are derivative-specific and exposure/iron-context dependent.

Primary mechanisms (ranked):

  1. Iron-dependent activation of the endoperoxide bridge causing ROS/lipid peroxidation stress and tumor-selective cytotoxicity (iron-high contexts)
  2. Ferroptosis sensitization/induction via iron handling and lipid peroxidation programs (often linked to ferritin/lysosome biology; context-dependent)
  3. Mitochondrial dysfunction with ΔΨm loss and intrinsic apoptosis signaling (downstream of oxidative stress)
  4. ER stress / UPR activation (stress-amplification axis)
  5. Hypoxia–metabolism suppression (HIF-1α and glycolysis program attenuation; model-dependent)
  6. Pro-survival inflammatory signaling suppression (e.g., NF-κB / STAT3 axes; model-dependent)

Bioavailability / PK relevance: Oral artemisinin has variable and generally limited systemic exposure with a short half-life on the order of hours; many anticancer in-vitro concentrations exceed typical achievable free-plasma levels without formulation strategies. Artesunate is rapidly converted to DHA; in an FDA label dataset (IV artesunate for severe malaria), artesunate has a very short half-life (~0.3 h) and DHA ~1.3 h, emphasizing exposure-time constraints and the need to interpret “ART/AS/DHA” PK separately.

In-vitro vs systemic exposure relevance: Many reported anticancer effects are driven by oxidative stress at micromolar in-vitro conditions and may be difficult to reproduce systemically without targeted delivery, local administration, or combination strategies that increase intratumoral iron/ROS burden (context-dependent).

Clinical evidence status: Cancer use remains investigational (preclinical-dominant with small/early human studies). Multiple registered clinical studies have evaluated artesunate/derivatives in oncology settings (e.g., phase I solid tumor IV artesunate; small/phase II-style neoadjuvant/adjunct trials), but there is no major regulatory approval for cancer indications; artesunate is approved/used clinically for severe malaria.

Artemisinin a compound in a Chinese herb that may inhibit tumor growth and metastasis Artemisinin (antimalarial drugs)
Artesunic acid (Artesunate) , Dihydroartemisinin (DHA), artesunate, arteether, and artemether, SM735, SM905, SM933, SM934, and SM1044

The induction of OS in tumor cells via the production of ROS is the key mechanism of ART against cancer.
combination of ART and Nrf2 inhibitors to promote ferroptosis may have more efficient anticancer effects without damaging normal cells.

Summary:
- One of the strongest tumor-selective pro-oxidants, mechanism related with iron. Synergizes with iron-rich tumors
-ROS seems to affect both cancer and normal cells
- Delivery of artemisinin in conjugate form with transferrin or holotransferrin (serum iron transport proteins) have been shown to greatly improve its effectiveness.
- Potential direct inhibitor of STAT3
- Artemisinin synergized with the glycolysis inhibitor 2DG (2-deoxy- D -glucose)
ART Combined Therapy: Allicin, Resveratrol, Curcumin, VitC (but not orally at same time), Butyrate , 2-DG, Aminolevulinic AcidG
-possible problems with liver toxicity??

-Artesunate (ART), an artemisinin compound, is known for lysosomal degradation of ferritin, inducing oxidative stress and promoting cancer cell death.

Pathways:
- Increasing reactive oxygen species (ROS) production. This oxidative stress can cause the loss of mitochondrial membrane potential, leading to cytochrome c release and subsequent activation of caspase cascades.
- Downregulate HIF-1α
- By impairing glycolysis, artemisinin might force cells to rely on oxidative phosphorylation (OXPHOS) for energy production.
- Inhibit GLUT1 (glucose uptake), HK2, PKM2 (slow the glycolytic flux, thereby reducing the energy supply)
- Minimal NRF2 activation

-Artemisinin has a half-life of about 3-4 hours, Artesunate 40 minutes and Artemether 12 hours. Peak plasma levels occur in 1-2 hour.
BioAv 21%, poor-good solubility. Artesunate (ART), a water soluble derivative of artemisinin. concentrations higher in blood, colon, liver, kidney (highly perfused organs)
Pathways:
- induce ROS production, iron dependent (affect both cancer and normal cells)
- ROS↑ related: MMP↓(ΔΨm), ER Stress↑, UPR↑, GRP78↑, Ca+2↑, Cyt‑c↑, Caspases↑, DNA damage↑, cl-PARP↑, HSP↓,
- Both Lowers (and raises) AntiOxidant defense in Cancer Cells: NRF2↓(contary), SOD↓, GSH↓ Catalase↓ GPx↓
- Small evidence of Raising AntiOxidant defense in Normal Cells: ROS↓(contary), NRF2↑, SOD↑(contary), GSH↑, Catalase↑,
- lowers Inflammation : NF-kB↓, COX2↓, p38↓, Pro-Inflammatory Cytokines : NLRP3↓, TNF-α↓, IL-6↓, IL-8↓
- inhibit Growth/Metastases : TumMeta↓, TumCG↓, EMT↓, MMPs↓, MMP2↓, MMP9↓, TIMP2, IGF-1↓, uPA↓, VEGF↓, ROCK1↓, NF-κB↓, TGF-β↓, ERK↓
- cause Cell cycle arrest : TumCCA↑, cyclin D1↓, cyclin E↓, CDK2↓, CDK4↓, CDK6↓,
- inhibits Migration/Invasion : TumCMig↓, TumCI↓, TNF-α↓, ERK↓, EMT↓, TOP1↓,
- inhibits glycolysis /Warburg Effect and ATP depletion : HIF-1α↓, PKM2↓, cMyc↓, GLUT1↓, LDH↓, LDHA↓, HK2↓, ECAR↓, GRP78↑, GlucoseCon↓
- inhibits angiogenesis↓ : VEGF↓, HIF-1α↓, EGFR↓, Integrins↓,
- some small indication of inhibiting Cancer Stem Cells : CSC↓, Hh↓, β-catenin↓, sox2↓, OCT4↓,
- Others: PI3K↓, AKT↓, JAK↓, STAT↓, Wnt↓, β-catenin↓, AMPK, ERK↓, JNK,
- Synergies: chemo-sensitization, RadioSensitizer, Others(review target notes),

- Selectivity: Cancer Cells vs Normal Cells
Often synergistic with ROS-based chemo

Artemisinin-class (ART/AS/DHA) mechanisms relevant to cancer biology

Rank Pathway / Axis Cancer Cells Normal Cells TSF Primary Effect Notes / Interpretation
1 Iron-activated endoperoxide chemistry and ROS burden ROS↑, lipid peroxidation↑, macromolecular damage↑ (iron-high contexts) ROS↔ to ↑ (dose-dependent) P Pro-oxidant, tumor-biased cytotoxic stress Core premise: iron availability (labile iron pool, heme/Fe²⁺ context) gates potency and selectivity; derivative and formulation matter.
2 Ferroptosis susceptibility Ferroptosis↑ (context-dependent), lipid-ROS↑ Ferroptosis↔ (context-dependent) R Non-apoptotic death program engagement or sensitization Evidence supports artemisinin-compounds as ferroptosis sensitizers/inducers in multiple models; often tied to iron handling and lipid peroxidation control nodes.
3 Ferritin and lysosome axis Ferritin turnover↑ / lysosomal iron↑ (model-dependent) → ROS↑ ↔ (model-dependent) R Iron mobilization that amplifies oxidative injury DHA/derivatives have been reported to engage ferritin/lysosome-related processes that increase reactive iron, supporting ferroptotic and apoptotic stress amplification.
4 Mitochondria and MPTP ΔΨm↓, mitochondrial ROS↑, Cyt-c release↑, apoptosis↑ Stress responses↔ to ↑ (dose-dependent) R Intrinsic apoptosis downstream of redox injury Mitochondrial impairment is commonly reported as a downstream execution route after ROS/iron activation; can intersect with ferroptosis via redox spillover.
5 ER stress and UPR ER stress↑, UPR↑ ↔ to ↑ (stress-dose dependent) R Proteostasis collapse / stress signaling Often co-occurs with ROS-driven injury; may contribute to growth arrest and death pathway crosstalk.
6 HIF-1α axis HIF-1α↓ (model-dependent) G Anti-hypoxic adaptation Reported suppression of hypoxia programs may reduce angiogenic and glycolytic adaptation in some tumors.
7 Glycolysis and glucose transport Glycolysis↓, GLUT1/HK2/PKM2↓ (model-dependent) ↔ (context-dependent) G Metabolic constraint Metabolic effects vary by cell state; can synergize with glycolysis inhibitors in model systems.
8 STAT3 axis STAT3↓ (model-dependent) G Pro-survival transcriptional attenuation Reported in subsets of studies; may contribute to reduced proliferation/survival signaling.
9 NF-κB and inflammatory signaling NF-κB↓, inflammatory cytokine programs↓ (model-dependent) Inflammation↓ (context-dependent) G Anti-inflammatory / pro-differentiation pressure Can be beneficial for tumor microenvironment modulation, but directionality and net effect depend on immune context.
10 NRF2 axis NRF2↔ (model-dependent; adaptive resistance possible) NRF2↔ to ↑ (context-dependent) G Redox adaptation gatekeeper NRF2 status can determine sensitivity vs resistance to ROS/ferroptosis; combinations that blunt NRF2 defenses are often proposed experimentally.
11 Clinical Translation Constraint Short exposure window; achievable concentrations may be below many in-vitro active ranges; heterogeneity in iron/redox state; derivative-specific PK Off-target oxidative stress risk (dose/formulation dependent) G Limits systemic reproducibility Interpret ART vs AS vs DHA separately; artesunate→DHA conversion is rapid and half-lives are short (route-dependent). Targeted delivery and combination strategies are common translational approaches.

TSF legend: P: 0–30 min    R: 30 min–3 hr    G: >3 hr
Glycolysis, Glycolysis: Click to Expand ⟱
Source:
Type:
Glycolysis is a metabolic pathway that converts glucose into pyruvate, producing a small amount of ATP (energy) in the process. It is a fundamental process for cellular energy production and occurs in the cytoplasm of cells. In normal cells, glycolysis is tightly regulated and is followed by aerobic respiration in the presence of oxygen, which allows for the efficient production of ATP.
In cancer cells, however, glycolysis is often upregulated, even in the presence of oxygen. This phenomenon is known as the Warburg Mutations in oncogenes (like MYC) and tumor suppressor genes (like TP53) can alter metabolic pathways, promoting glycolysis and other anabolic processes that support cell growth.effect.
Acidosis: The increased production of lactate from glycolysis can lead to an acidic microenvironment, which may promote tumor invasion and suppress immune responses.

Glycolysis is a hallmark of malignancy transformation in solid tumor, and LDH is the key enzyme involved in glycolysis.

Pathways:
-GLUTs, HK2, PFK, PK, PKM2, LDH, LDHA, PI3K/AKT/mTOR, AMPK, HIF-1a, c-MYC, p53, SIRT6, HSP90α, GAPDH, HBT, PPP, Lactate Metabolism, ALDO

Natural products targeting glycolytic signaling pathways https://pmc.ncbi.nlm.nih.gov/articles/PMC9631946/
Alkaloids:
-Berberine, Worenine, Sinomenine, NK007, Tetrandrine, N-methylhermeanthidine chloride, Dauricine, Oxymatrine, Matrine, Cryptolepine

Flavonoids: -Oroxyline A, Apigenin, Kaempferol, Quercetin, Wogonin, Baicalein, Chrysin, Genistein, Cardamonin, Phloretin, Morusin, Bavachinin, 4-O-methylalpinumisofavone, Glabridin, Icaritin, LicA, Naringin, IVT, Proanthocyanidin B2, Scutellarin, Hesperidin, Silibinin, Catechin, EGCG, EGC, Xanthohumol.

Non-flavonoid phenolic compounds:
Curcumin, Resveratrol, Gossypol, Tannic acid.

Terpenoids:
-Cantharidin, Dihydroartemisinin, Oleanolic acid, Jolkinolide B, Cynaropicrin, Ursolic Acid, Triptolie, Oridonin, Micheliolide, Betulinic Acid, Beta-escin, Limonin, Bruceine D, Prosapogenin A (PSA), Oleuropein, Dioscin.

Quinones:
-Thymoquinone, Lapachoi, Tan IIA, Emodine, Rhein, Shikonin, Hypericin

Others:
-Perillyl alcohol, HCA, Melatonin, Sulforaphane, Vitamin D3, Mycoepoxydiene, Methyl jasmonate, CK, Phsyciosporin, Gliotoxin, Graviola, Ginsenoside, Beta-Carotene.
Scientific Papers found: Click to Expand⟱
3383- ART/DHA,    Dihydroartemisinin: A Potential Natural Anticancer Drug
- Review, Var, NA
TumCP↓, DHA exerts anticancer effects through various molecular mechanisms, such as inhibiting proliferation, inducing apoptosis, inhibiting tumor metastasis and angiogenesis, promoting immune function, inducing autophagy and endoplasmic reticulum (ER) stres
Apoptosis↑,
TumMeta↓,
angioG↓,
TumAuto↑,
ER Stress↑,
ROS↑, DHA could increase the level of ROS in cells, thereby exerting a cytotoxic effect in cancer cells
Ca+2↑, activation of Ca2+ and p38 was also observed in DHA-induced apoptosis of PC14 lung cancer cells
p38↑,
HSP70/HSPA5↓, down-regulation of heat-shock protein 70 (HSP70) might participate in the apoptosis of PC3 prostate cancer cells induced by DHA
PPARγ↑, DHA inhibited the growth of colon tumor by inducing apoptosis and increasing the expression of peroxisome proliferator-activated receptor γ (PPARγ)
GLUT1↓, DHA was shown to inhibit the activity of glucose transporter-1 (GLUT1) and glycolytic pathway by inhibiting phosphatidyl-inositol-3-kinase (PI3K)/AKT pathway and downregulating the expression of hypoxia inducible factor-1α (HIF-1α)
Glycolysis↓, Inhibited glycolysis
PI3K↓,
Akt↓,
Hif1a↓,
PKM2↓, DHA could inhibit the expression of PKM2 as well as inhibit lactic acid production and glucose uptake, thereby promoting the apoptosis of esophageal cancer cells
lactateProd↓,
GlucoseCon↓,
EMT↓, regulating the EMT-related genes (Slug, ZEB1, ZEB2 and Twist)
Slug↓, Downregulated Slug, ZEB1, ZEB2 and Twist in mRNA level
Zeb1↓,
ZEB2↓,
Twist↓,
Snail?, downregulated the expression of Snail and PI3K/AKT signaling pathway, thereby inhibiting metastasis
CAFs/TAFs↓, DHA suppressed the activation of cancer-associated fibroblasts (CAFs) and mouse cancer-associated fibroblasts (L-929-CAFs) by inhibiting transforming growth factor-β (TGF-β signaling
TGF-β↓,
p‑STAT3↓, blocking the phosphorylation of STAT3 and polarization of M2 macrophages
M2 MC↓,
uPA↓, DHA could inhibit the growth and migration of breast cancer cells by inhibiting the expression of uPA
HH↓, via inhibiting the hedgehog signaling pathway
AXL↓, DHA acted as an Axl inhibitor in prostate cancer, blocking the expression of Axl through the miR-34a/miR-7/JARID2 pathway, thereby inhibiting the proliferation, migration and invasion of prostate cancer cells.
VEGFR2↓, inhibition of VEGFR2-mediated angiogenesis
JNK↑, JNK pathway activated and Beclin 1 expression upregulated.
Beclin-1↑,
GRP78/BiP↑, Glucose regulatory protein 78 (GRP78, an ER stress-related molecule) was upregulated after DHA treatment.
eff↑, results demonstrated that DHA-induced ER stress required iron
eff↑, DHA was used in combination with PDGFRα inhibitors (sunitinib and sorafenib), it could sensitize ovarian cancer cells to PDGFR inhibitors and achieved effective therapeutic efficacy
eff↑, DHA combined with 2DG (a glycolysis inhibitor) synergistically induced apoptosis through both exogenous and endogenous apoptotic pathways
eff↑, histone deacetylase inhibitors (HDACis) enhanced the anti-tumor effect of DHA by inducing apoptosis.
eff↑, DHA enhanced PDT-induced cell growth inhibition and apoptosis, increased the sensitivity of esophageal cancer cells to PDT by inhibiting the NF-κB/HIF-1α/VEGF pathway
eff↑, DHA was added to magnetic nanoparticles (MNP), and the MNP-DHA has shown an effect in the treatment of intractable breast cancer
IL4↓, downregulated IL-4;
DR5↑, Upregulated DR5 in protein, Increased DR5 promoter activity
Cyt‑c↑, Released cytochrome c from the mitochondria to the cytosol
Fas↑, Upregulated fas, FADD, Bax, cleaved-PARP
FADD↑,
cl‑PARP↑,
cycE/CCNE↓, Downregulated Bcl-2, Bcl-xL, procaspase-3, Cyclin E, CDK2 and CDK4
CDK2↓,
CDK4↓,
Mcl-1↓, Downregulated Mcl-1
Ki-67↓, Downregulated Ki-67 and Bcl-2
Bcl-2↓,
CDK6↓, Downregulated of Cyclin E, CDK2, CDK4 and CDK6
VEGF↓, Downregulated VEGF, COX-2 and MMP-9
COX2↓,
MMP9↓,

957- ART/DHA,    Artemisinin inhibits the development of esophageal cancer by targeting HIF-1α to reduce glycolysis levels
- in-vitro, ESCC, KYSE150 - in-vitro, ESCC, KYSE170
TumCP↓,
TumMeta↓,
Glycolysis↓,
N-cadherin↓,
PKM2↓,
Hif1a↓,

985- ART/DHA,    Artemisinin suppresses aerobic glycolysis in thyroid cancer cells by downregulating HIF-1a, which is increased by the XIST/miR-93/HIF-1a pathway
- in-vitro, Thyroid, TPC-1 - Human, NA, NA
XIST↓, HIF-1a is highly expressed in TC tissues and is positively correlated with the level of XIST in the serum of patients with TC.
Hif1a↓,
Glycolysis↓,
TumCCA↑, inhibited the cell cycle, and G1 phase cells increased by 17%
TumMeta↓, 51%

2324- ART/DHA,    Research Progress of Warburg Effect in Hepatocellular Carcinoma
- Review, Var, NA
PKM2↓, DHA effectively suppressed aerobic glycolysis and ESCC progression by downregulating PKM2 expression in esophageal squamous cell carcinoma (ESCC) and ESCC cells
GLUT1↓, DHA inhibited leukemia cell K562 proliferation by suppressing GLUT1 and PKM2 levels, thereby regulating glucose uptake and inhibiting aerobic glycolysis
Glycolysis↓,
Akt↓, In LNCaP cells, DHA reduced Akt/mTOR and HIF-1α activity, leading to decreased expression of GLUT1, HK2, PKM2, and LDH and subsequent inhibition of aerobic glycolysis
mTOR↓,
Hif1a↓,
HK2↓,
LDH↓,
NF-kB↓, DHA was also found to inhibit the NF-κB signaling pathway to prevent GLUT1 translocation to the plasma membrane, thereby inhibiting the progression of non-small-cell lung cancer (NSCLC) cells via targeting glucose metabolism

2322- ART/DHA,    Dihydroartemisinin Regulates Self-Renewal of Human Melanoma-Initiating Cells by Targeting PKM2/LDHARelated Glycolysis
- in-vitro, Melanoma, NA
TumCP↓, DHA inhibits the proliferation of melanoma cells and blocks the cell cycle process.
PKM2↓, DHA reduces ATP production and downregulate PKM2 and LDHA activities without regulating the expression of the PKM2 and LDHA proteins in melanoma cells
LDHA↓,
Glycolysis↓, downregulates glucose metabolism in melanoma cells.

2320- ART/DHA,    Dihydroartemisinin Inhibits the Proliferation of Leukemia Cells K562 by Suppressing PKM2 and GLUT1 Mediated Aerobic Glycolysis
- in-vitro, AML, K562 - in-vitro, Liver, HepG2
Glycolysis↓, DHA prevented cell proliferation in K562 cells through inhibiting aerobic glycolysis.
GlucoseCon↓, Lactate product and glucose uptake were inhibited after DHA treatment.
lactateProd↓,
GLUT1↓, DHA modulates glucose uptake through downregulating glucose transporter 1 (GLUT1) in both gene and protein levels.
PKM2↓, DHA treatment, decreased expression of PKM2 was confirmed in situ.
ECAR↓, ECAR parameters including the glycolytic activity and capacity decreased in a concentration-dependent manner in K562 cells following DHA administration
LDHA↓, DHA treatment downregulated the relative expression of GLUT1, PKM2, LDH-A and c-Myc
cMyc↓,
other↝, The relative changes of PDK1, P53, HIF-1α, HK2, and PFK1 expression were modest, with most genes being altered by less than 2-fold


* indicates research on normal cells as opposed to diseased cells
Total Research Paper Matches: 6

Pathway results for Effect on Cancer / Diseased Cells:


Redox & Oxidative Stress

ROS↑, 1,  

Core Metabolism/Glycolysis

cMyc↓, 1,   ECAR↓, 1,   GlucoseCon↓, 2,   Glycolysis↓, 6,   HK2↓, 1,   lactateProd↓, 2,   LDH↓, 1,   LDHA↓, 2,   PKM2↓, 5,   PPARγ↑, 1,  

Cell Death

Akt↓, 2,   Apoptosis↑, 1,   Bcl-2↓, 1,   Cyt‑c↑, 1,   DR5↑, 1,   FADD↑, 1,   Fas↑, 1,   JNK↑, 1,   Mcl-1↓, 1,   p38↑, 1,  

Transcription & Epigenetics

other↝, 1,  

Protein Folding & ER Stress

ER Stress↑, 1,   GRP78/BiP↑, 1,   HSP70/HSPA5↓, 1,  

Autophagy & Lysosomes

Beclin-1↑, 1,   TumAuto↑, 1,  

DNA Damage & Repair

cl‑PARP↑, 1,  

Cell Cycle & Senescence

CDK2↓, 1,   CDK4↓, 1,   cycE/CCNE↓, 1,   TumCCA↑, 1,  

Proliferation, Differentiation & Cell State

EMT↓, 1,   HH↓, 1,   mTOR↓, 1,   PI3K↓, 1,   p‑STAT3↓, 1,  

Migration

AXL↓, 1,   Ca+2↑, 1,   CAFs/TAFs↓, 1,   Ki-67↓, 1,   MMP9↓, 1,   N-cadherin↓, 1,   Slug↓, 1,   Snail?, 1,   TGF-β↓, 1,   TumCP↓, 3,   TumMeta↓, 3,   Twist↓, 1,   uPA↓, 1,   Zeb1↓, 1,   ZEB2↓, 1,  

Angiogenesis & Vasculature

angioG↓, 1,   Hif1a↓, 4,   VEGF↓, 1,   VEGFR2↓, 1,  

Barriers & Transport

GLUT1↓, 3,  

Immune & Inflammatory Signaling

COX2↓, 1,   IL4↓, 1,   M2 MC↓, 1,   NF-kB↓, 1,  

Hormonal & Nuclear Receptors

CDK6↓, 1,  

Drug Metabolism & Resistance

eff↑, 6,  

Clinical Biomarkers

Ki-67↓, 1,   LDH↓, 1,   XIST↓, 1,  
Total Targets: 66

Pathway results for Effect on Normal Cells:


Total Targets: 0

Scientific Paper Hit Count for: Glycolysis, Glycolysis
6 Artemisinin
Query results interpretion may depend on "conditions" listed in the research papers.
Such Conditions may include : 
  -low or high Dose
  -format for product, such as nano of lipid formations
  -different cell line effects
  -synergies with other products 
  -if effect was for normal or cancerous cells

Filter Conditions: Pro/AntiFlg:%  IllCat:%  CanType:%  Cells:%  prod#:34  Target#:129  State#:%  Dir#:%
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