NOTCH Cancer Research Results

NOTCH, : Click to Expand ⟱
Source: HalifaxProj(block) CGL-CF TCGA
Type:
Notch signaling pathway is a regulator of self-renewal and differentiation in several tissues and cell types.; Notch hyperactivation has been implicated as oncogenic in several cancers including breast cancer and T-cell acute lymphoblastic leukemia (T-ALL).
Due to its dual roles, NOTCH signaling is being explored as a therapeutic target. Inhibitors of NOTCH signaling are being investigated in clinical trials for various cancers, particularly those with aberrant NOTCH activation.
The abnormal activation of the NOTCH pathway has been linked to increased cancer cell growth, survival, invasion, and resistance to chemotherapy and radiation therapy. On the other hand, blocking the NOTCH pathway has been shown to trigger cancer cell differentiation and cell death, and it makes them more responsive to therapy. Hence, inhibiting the NOTCH pathway has become a promising approach for treating cancer, and various NOTCH pathway inhibitors are currently under development for cancer treatment.
Scientific Papers found: Click to Expand⟱
3160- Ash,    Withaferin A: A Pleiotropic Anticancer Agent from the Indian Medicinal Plant Withania somnifera (L.) Dunal
- Review, Var, NA
TumCCA↑, withaferin A suppressed cell proliferation in prostate, ovarian, breast, gastric, leukemic, and melanoma cancer cells and osteosarcomas by stimulating the inhibition of the cell cycle at several stages, including G0/G1 [86], G2, and M phase
H3↑, via the upregulation of phosphorylated Aurora B, H3, p21, and Wee-1, and the downregulation of A2, B1, and E2 cyclins, Cdc2 (Tyr15), phosphorylated Chk1, and Chk2 in DU-145 and PC-3 prostate cancer cells.
P21↑,
cycA1/CCNA1↓,
CycB/CCNB1↓,
cycE/CCNE↓,
CDC2↓,
CHK1↓,
Chk2↓,
p38↑, nitiated cell death in the leukemia cells by increasing the expression of p38 mitogen-activated protein kinases (MAPK)
MAPK↑,
E6↓, educed the expression of human papillomavirus E6/E7 oncogenes in cervical cancer cells
E7↓,
P53↑, restored the p53 pathway causing the apoptosis of cervical cancer cells.
Akt↓, oral dose of 3–5 mg/kg withaferin A attenuated the activation of Akt and stimulated Forkhead Box-O3a (FOXO3a)-mediated prostate apoptotic response-4 (Par-4) activation,
FOXO3↑,
ROS↑, the generation of reactive oxygen species, histone H2AX phosphorylation, and mitochondrial membrane depolarization, indicating that withaferin A can cause the oxidative stress-mediated killing of oral cancer cells [
γH2AX↑,
MMP↓,
mitResp↓, withaferin A inhibited the expansion of MCF-7 and MDA-MB-231 human breast cancer cells by ROS production, owing to mitochondrial respiration inhibition
eff↑, combination treatment of withaferin A and hyperthermia induced the death of HeLa cells via a decrease in the mitochondrial transmembrane potential and the downregulation of the antiapoptotic protein myeloid-cell leukemia 1 (MCL-1)
TumCD↑,
Mcl-1↓,
ER Stress↑, . Withaferin A also attenuated the development of glioblastoma multiforme (GBM), both in vitro and in vivo, by inducing endoplasmic reticulum stress via activating the transcription factor 4-ATF3-C/EBP homologous protein (ATF4-ATF3-CHOP)
ATF4↑,
ATF3↑,
CHOP↑,
NOTCH↓, modulating the Notch-1 signaling pathway and the downregulation of Akt/NF-κB/Bcl-2 . withaferin A inhibited the Notch signaling pathway
NF-kB↓,
Bcl-2↓,
STAT3↓, Withaferin A also constitutively inhibited interleukin-6-induced phosphorylation of STAT3,
CDK1↓, lowering the levels of cyclin-dependent Cdk1, Cdc25C, and Cdc25B proteins,
β-catenin/ZEB1↓, downregulation of p-Akt expression, β-catenin, N-cadherin and epithelial to the mesenchymal transition (EMT) markers
N-cadherin↓,
EMT↓,
Cyt‑c↑, depolarization and production of ROS, which led to the release of cytochrome c into the cytosol,
eff↑, combinatorial effect of withaferin A and sulforaphane was also observed in MDA-MB-231 and MCF-7 breast cancer cells, with a dramatic reduction of the expression of the antiapoptotic protein Bcl-2 and an increase in the pro-apoptotic Bax level, thus p
CDK4↓, downregulates the levels of cyclin D1, CDK4, and pRB, and upregulates the levels of E2F mRNA and tumor suppressor p21, independently of p53
p‑RB1↓,
PARP↑, upregulation of Bax and cytochrome c, downregulation of Bcl-2, and activation of PARP, caspase-3, and caspase-9 cleavage
cl‑Casp3↑,
cl‑Casp9↑,
NRF2↑, withaferin A binding with Keap1 causes an increase in the nuclear factor erythroid 2-related factor 2 (Nrf2) protein levels, which in turn, regulates the expression of antioxidant proteins that can protect the cells from oxidative stress.
ER-α36↓, Decreased ER-α
LDHA↓, inhibited growth, LDHA activity, and apoptotic induction
lipid-P↑, induction of oxidative stress, increased lipid peroxidation,
AP-1↓, anti-inflammatory qualities of withaferin A are specifically attributed to its inhibition of pro-inflammatory molecules, α-2 macroglobulin, NF-κB, activator protein 1 (AP-1), and cyclooxygenase-2 (COX-2) inhibition,
COX2↓,
RenoP↑, showing strong evidence of the renoprotective potential of withaferin A due to its anti-inflammatory activity
PDGFR-BB↓, attenuating the BB-(PDGF-BB) platelet growth factor
SIRT3↑, by increasing the sirtuin3 (SIRT3) expression
MMP2↓, withaferin A inhibits matrix metalloproteinase-2 (MMP-2) and MMP-9,
MMP9↓,
NADPH↑, but also provokes mRNA stimulation for a set of antioxidant genes, such as NADPH quinone dehydrogenase 1 (NQO1), glutathione-disulfide reductase (GSR), Nrf2, heme oxygenase 1 (HMOX1),
NQO1↑,
GSR↑,
HO-1↑,
*SOD2↑, cardiac ischemia-reperfusion injury model. Withaferin A triggered the upregulation of superoxide dismutase SOD2, SOD3, and peroxiredoxin 1(Prdx-1).
*Prx↑,
*Casp3?, and ameliorated cardiomyocyte caspase-3 activity
eff↑, combination with doxorubicin (DOX), is also responsible for the excessive generation of ROS
Snail↓, inhibition of EMT markers, such as Snail, Slug, β-catenin, and vimentin.
Slug↓,
Vim↓,
CSCs↓, highly effective in eliminating cancer stem cells (CSC) that expressed cell surface markers, such as CD24, CD34, CD44, CD117, and Oct4 while downregulating Notch1, Hes1, and Hey1 genes;
HEY1↓,
MMPs↓, downregulate the expression of MMPs and VEGF, as well as reduce vimentin, N-cadherin cytoskeleton proteins,
VEGF↓,
uPA↓, and protease u-PA involved in the cancer cell metastasis
*toxicity↓, A was orally administered to Wistar rats at a dose of 2000 mg/kg/day and had no adverse effects on the animals
CDK2↓, downregulated the activation of Bcl-2, CDK2, and cyclin D1
CDK4↓, Another study also demonstrated the inhibition of Hsp90 by withaferin A in a pancreatic cancer cell line through the degradation of Akt, cyclin-dependent kinase 4 Cdk4,
HSP90↓,

2617- Ba,    Potential of baicalein in the prevention and treatment of cancer: A scientometric analyses based review
- Review, Var, NA
Ca+2↑, MDA-MB-231 ↑Ca2+
MMP2↓, MDA-MB-231 ↓MMP-2/9
MMP9↓,
Vim↓, ↓Vimentin, ↓SNAIL, ↑E-cadherin, ↓Wnt1, ↓β-catenin
Snail↓,
E-cadherin↑,
Wnt↓,
β-catenin/ZEB1↓,
p‑Akt↓, MCF-7 ↓p-Akt, ↓p-mTOR, ↓NF-κB
p‑mTOR↓,
NF-kB↓,
i-ROS↑, MCF-7 ↑Intracellular ROS, ↓Bcl-2, ↑Bax, ↑cytochrome c, ↑caspase-3/9
Bcl-2↓,
BAX↑,
Cyt‑c↑,
Casp3↑,
Casp9↑,
STAT3↓, 4T1, MDA-MB-231 ↓STAT3, ↓ IL-6
IL6↓,
MMP2↓, HeLa ↓MMP-2, ↓MMP-9
MMP9↓,
NOTCH↓, ↓Notch 1
PPARγ↓, ↓PPARγ
p‑NRF2↓, HCT-116 ↓p-Nrf2
HK2↓, ↓HK2, ↓LDH-A, ↓PDK1, ↓glycolysis, PTEN/Akt/HIF-1α regulation
LDHA↓,
PDK1↓,
Glycolysis↓,
PTEN↑, Furthermore, baicalein inhibited hypoxia-induced Akt phosphorylation by promoting PTEN accumulation, thereby attenuating hypoxia-inducible factor-alpha ( HIF-1a) expression in AGS cells.
Akt↓,
Hif1a↓,
MMP↓, SGC-7901 ↓ΔΨm
VEGF↓, ↓VEGF, ↓VEGFR2
VEGFR2↓,
TOP2↓, ↓Topoisomerase II
uPA↓, ↓u-PA, ↓TIMP1, ↓TIMP2
TIMP1↓,
TIMP2↓,
cMyc↓, ↓β-catenin, ↓c-Myc, ↓cyclin D1, ↓Axin-2
TrxR↓, EL4 ↓Thioredoxin reductase, ↑ASK1,
ASK1↑,
Vim↓, ↓vimentin
ZO-1↑, ↑ZO-1
E-cadherin↑, ↑E-cadherin
SOX2↓, PANC-1, BxPC-3, SW1990 ↓Sox-2, ↓Oct-4, ↓SHH, ↓SMO, ↓Gli-2
OCT4↓,
Shh↓,
Smo↓,
Gli1↓,
N-cadherin↓, ↓N-cadherin
XIAP↓, ↓XIAP

2686- BBR,    Effects of resveratrol, curcumin, berberine and other nutraceuticals on aging, cancer development, cancer stem cells and microRNAs
- Review, Nor, NA
Inflam↓, BBR has documented to have anti-diabetic, anti-inflammatory and anti-microbial (both anti-bacterial and anti-fungal) properties.
IL6↓, BBRs can inhibit IL-6, TNF-alpha, monocyte chemo-attractant protein 1 (MCP1) and COX-2 production and expression.
MCP1↓,
COX2↓,
PGE2↓, BBRs can also effect prostaglandin E2 (PGE2)
MMP2↓, and decrease the expression of key genes involved in metastasis including: MMP2 and MMP9.
MMP9↓,
DNAdam↑, BBR induces double strand DNA breaks and has similar effects as ionizing radiation
eff↝, In some cell types, this response has been reported to be TP53-dependent
Telomerase↓, This positively-charged nitrogen may result in the strong complex formations between BBR and nucleic acids and induce telomerase inhibition and topoisomerase poisoning
Bcl-2↓, BBR have been shown to suppress BCL-2 and expression of other genes by interacting with the TATA-binding protein and the TATA-box in certain gene promoter regions
AMPK↑, BBR has been shown in some studies to localize to the mitochondria and inhibit the electron transport chain and activate AMPK.
ROS↑, targeting the activity of mTOR/S6 and the generation of ROS
MMP↓, BBR has been shown to decrease mitochondrial membrane potential and intracellular ATP levels.
ATP↓,
p‑mTORC1↓, BBR induces AMPK activation and inhibits mTORC1 phosphorylation by suppressing phosphorylation of S6K at Thr 389 and S6 at Ser 240/244
p‑S6K↓,
ERK↓, BBR also suppresses ERK activation in MIA-PaCa-2 cells in response to fetal bovine serum, insulin or neurotensin stimulation
PI3K↓, Activation of AMPK is associated with inhibition of the PI3K/PTEN/Akt/mTORC1 and Raf/MEK/ERK pathways which are associated with cellular proliferation.
PTEN↑, RES was determined to upregulate phosphatase and tensin homolog (PTEN) expression and decrease the expression of activated Akt. In HCT116 cells, PTEN inhibits Akt signaling and proliferation.
Akt↓,
Raf↓,
MEK↓,
Dose↓, The effects of low doses of BBR (300 nM) on MIA-PaCa-2 cells were determined to be dependent on AMPK as knockdown of the alpha1 and alpha2 catalytic subunits of AMPK prevented the inhibitory effects of BBR on mTORC1 and ERK activities and DNA synthes
Dose↑, In contrast, higher doses of BBR inhibited mTORC1 and ERK activities and DNA synthesis by AMPK-independent mechanisms [223,224].
selectivity↑, BBR has been shown to have minimal effects on “normal cells” but has anti-proliferative effects on cancer cells (e.g., breast, liver, CRC cells) [225–227].
TumCCA↑, BBR induces G1 phase arrest in pancreatic cancer cells, while other drugs such as gemcitabine induce S-phase arrest
eff↑, BBR was determined to enhance the effects of epirubicin (EPI) on T24 bladder cancer cells
EGFR↓, In some glioblastoma cells, BBR has been shown to inhibit EGFR signaling by suppression of the Raf/MEK/ERK pathway but not AKT signaling
Glycolysis↓, accompanied by impaired glycolytic capacity.
Dose?, The IC50 for BBR was determined to be 134 micrograms/ml.
p27↑, Increased p27Kip1 and decreased CDK2, CDK4, Cyclin D and Cyclin E were observed.
CDK2↓,
CDK4↓,
cycD1/CCND1↓,
cycE/CCNE↓,
Bax:Bcl2↑, Increased BAX/BCL2 ratio was observed.
Casp3↑, The mitochondrial membrane potential was disrupted and activated caspase 3 and caspases 9 were observed
Casp9↑,
VEGFR2↓, BBR treatment decreased VEGFR, Akt and ERK1,2 activation and the expression of MMP2 and MMP9 [235].
ChemoSen↑, BBR has been shown to increase the anti-tumor effects of tamoxifen (TAM) in both drug-sensitive MCF-7 and drug-resistant MCF-7/TAM cells.
eff↑, The combination of BBR and CUR has been shown to be effective in suppressing the growth of certain breast cancer cell lines.
eff↑, BBR has been shown to synergize with the HSP-90 inhibitor NVP-AUY922 in inducing death of human CRC.
PGE2↓, BBR inhibits COX2 and PEG2 in CRC.
JAK2↓, BBR prevented the invasion and metastasis of CRC cells via inhibiting the COX2/PGE2 and JAK2/STAT3 signaling pathways.
STAT3↓,
CXCR4↓, BBR has been observed to inhibit the expression of the chemokine receptors (CXCR4 and CCR7) at the mRNA level in esophageal cancer cells.
CCR7↓,
uPA↓, BBR has also been shown to induce plasminogen activator inhibitor-1 (PAI-1) and suppress uPA in HCC cells which suppressed their invasiveness and motility.
CSCs↓, BBR has been shown to inhibit stemness, EMT and induce neuronal differentiation in neuroblastoma cells. BBR inhibited the expression of many genes associated with neuronal differentiation
EMT↓,
Diff↓,
CD133↓, BBR also suppressed the expression of many genes associated with cancer stemness such as beta-catenin, CD133, NESTIN, N-MYC, NOTCH and SOX2
Nestin↓,
n-MYC↓,
NOTCH↓,
SOX2↓,
Hif1a↓, BBR inhibited HIF-1alpha and VEGF expression in prostate cancer cells and increased their radio-sensitivity in in vitro as well as in animal studies [290].
VEGF↓,
RadioS↑,

1450- Bos,  Cisplatin,    3-Acetyl-11-keto-β-boswellic acid (AKBA) induced antiproliferative effect by suppressing Notch signaling pathway and synergistic interaction with cisplatin against prostate cancer cells
- in-vitro, Pca, DU145
ROS↑, increased reactive oxygen species (ROS) generation
MMP↓,
Casp↑,
Apoptosis↑,
Bax:Bcl2↑,
TumCCA?, induce G0/G1 arrest
cycD1/CCND1↓,
CDK4↓,
P21↑,
p27↑,
NOTCH↓, AKBA demonstrated significant downregulation of Notch signaling mediators
ChemoSen↑, AKBA has the potential to synergistically enhance the cytotoxic efficacy of cisplatin

5888- CAR,    Therapeutic application of carvacrol: A comprehensive review
- Review, Var, NA - Review, Stroke, NA - Review, Diabetic, NA - Review, Park, NA
*antiOx↑, demonstrated as anti‐oxidant, anticancer, diabetes prevention, cardioprotective, anti‐obesity, hepatoprotective and reproductive role, antiaging, antimicrobial, and immunomodulatory properties.
*AntiCan↑,
*AntiDiabetic↑,
*cardioP↑,
*Obesity↓,
*hepatoP↑,
*AntiAg↑,
*Bacteria↓,
*Imm↑,
MMP2↓, anticancer ability against malignant cells via decreasing the expressions of matrix metalloprotease 2 and 9, inducing apoptosis
MMP9↓,
Apoptosis↓,
MMP↓, disrupting mitochondrial membrane, suppressing extracellular signal‐regulated kinase 1/2 mitogen‐activated protein kinase signal transduction
ERK↓,
PI3K↓, decreasing the phosphoinositide 3‐kinase/protein kinase B.
ALAT↓, decreased the concentrations of alanine aminotransferase, alkaline phosphatase and aspartate aminotransferase,
*ROS↓, Essential oils found in plants are natural anti‐oxidants that reduce cell damage caused by reactive species and prevent mutagenic and carcinogenic processes.
*Catalase↑, Carvacrol has remarkably higher anti‐oxidative and hepatoprotective properties, which improves the activity of enzymatic anti‐oxidants (catalase, superoxide dismutase, and glutathione peroxidase)
*SOD↑,
*GPx↑,
*AST↓, Carvacrol decreased the level of aspartate aminotransferase (AST), alanine aminotransferase (ALT), and lactic acid dehydrogenase (LDH) and improved the status of inflammation, necrosis, and coagulation in the liver
*LDH↓,
*necrosis↓,
ROS↑, prostate cancer cells via lowering cell viability, increasing the rate of reactive oxygen species, and disrupting the mitochondrial membrane potential.
TumCCA↑, Carvacrol induced cell cycle arrest at G0/G1 that declined increased CDK inhibitor p21 expression and decreased cyclin‐dependent kinase 4 (CDK4), and cyclin D1 expressions.
CDK4↓,
cycD1/CCND1↓,
NOTCH↓, carvacrol inhibited Notch signaling in PC‐3 cells via downregulating Jagged‐1 and Notch‐1
IL6↓, human prostate cancer cell lines, which significantly reduced IL‐6
chemoP↑, Carvacrol has significant protective effects in reducing the side effects of chemotherapeutics such as irinotecan hydrochloride anticancer drugs that cause induction of intestinal mucositis.
*Pain↓, Pain management
*neuroP↑, The neuroprotective role of carvacrol was examined by Guan et al. in 2019 against ischemic stroke,
*TRPM7↓, downregulating TRPM7 channels
*motorD↑, improved catalepsy, akinesia, bradykinesia, locomotor activity, and motor coordination.
*NF-kB↓, Carvacrol reduced inflammatory biomarkers, such as nuclear factor κB and cyclooxygenase‐2, and levels of nitric oxides, malondialdehyde, and glutathione create oxidative stress.
*COX2↓,
*MDA↓,

5893- CAR,  TV,    Thymol and Carvacrol: Molecular Mechanisms, Therapeutic Potential, and Synergy With Conventional Therapies in Cancer Management
- Review, Var, NA
*Inflam↓, Monoterpenes like thymol and carvacrol are recognized for their anti‐inflammatory and anticancer properties,
AntiCan↑,
PI3K↓, Thymol derivatives, such as 1,2,3‐triazoles and carvacrol, effectively target breast cancer (BC) through PI3K/AKT/mTOR and NOTCH pathways and inhibit PIK3CA expression.
Akt↓,
mTOR↓,
NOTCH↓,
PIK3CA↓,
EGFR↓, thymol exhibits anti‐EGFR activity, while carvacrol modulates the HIF‐1α/VEGF pathway, making them potential candidates for colorectal cancer (CRC) management.
Hif1a↓,
VEGF↓,
ChemoSen↑, Their synergistic potential with chemotherapy, radiotherapy, and other bioactive compounds strengthens their therapeutic promise.
RadioS↑,
eff↝, challenges such as stability, bioavailability, and the need for clinical trials hinder their clinical application.
*cardioP↑, cardioprotective (Joshi et al. 2023), neuroprotective (Forqani et al. 2023) and hepato‐nephroprotective
*neuroP↑,
*hepatoP↑,
Apoptosis↑, Induction of Apoptosis
MMP↓, The apoptosis was due to ROS production, variations in the mitochondrial membrane, caspase‐3 activation, and DNA damage
Casp3↑,
ROS↑,
DNAdam↑,
eff↑, Thymol derivative, known as compound 10 (IC50 6.17 μM) exhibited 3.2‐fold more inhibition than 5‐fluorouracil (IC50 20.09 μM) against MCF‐7
BAX↑, Carvacrol (25, 50, 75, and 90 μM) enhanced the expression of Bax, Bad, Fas‐L, and cytochrome c, activated caspase‐9/3 and caspase‐8, induced cell cycle at G0/G1
BAD↑,
FasL↑,
Cyt‑c↑,
Casp9↑,
Casp8↑,
TumCCA↑,
P21↑, improved the expression of proteins (p21, cyclin D1, CDK4), and downregulated the SMO and GLI1 proteins expression in CC
Smo↓,
Gli1↓,
JNK↑, Moreover, thymol activated JNK and p38 MAPK while impeding the ERK pathway
ERK↓,
MAPK↓, Besides thymol, carvacrol has also been reported to inhibit MAPK or ERK pathways in previous studies.
TRPM7↓, inhibited TRPM7 expression in liver fibrotic C57BL/6J mice
Wnt/(β-catenin)↓, hymol inhibited HCT116 and LoVo cell line invasion via downregulating the Wnt/β‐catenin pathway and reducing c‐Myc and Cyclin D1 expression
BioAv↝, thymol and carvacrol are volatile, and their stability is influenced by these factors (temperature, light, oxygen, and pH)
BioAv↑, Ultrasonication is an effective technique to enhance the stability of thymol and other bioactive compounds. 400 watts of power elevated the performance of NC‐CH formulations, and NC‐CH‐400 displayed increased solubility.

5891- CAR,  SRF,    Carvacrol enhances anti-tumor activity and mitigates cardiotoxicity of sorafenib in thioacetamide-induced hepatocellular carcinoma model through inhibiting TRPM7
- in-vivo, HCC, NA
eff↑, CARV/Sora combination significantly improved survival rate, and liver functions, reduced Alpha-Fetoprotein level, and attenuated HCC progression compared with Sora group
OS↑,
hepatoP↑,
AFP↓,
NOTCH↓, downregulating ATP-binding cassette subfamily G member 2, NOTCH1, Spalt like transcription factor 4, and CD133.
cycD1/CCND1↓, decreasing cyclin D1 and B-cell leukemia/lymphoma 2 and increasing BCL2-Associated X and caspase-3.
Bcl-xL↑,
Casp3↑,
TRPM7↓, CARV/Sora is a promising combination for tumor suppression and overcoming Sora resistance and cardiotoxicity in HCC by modulating TRPM7
Dose↝, CARV (15 mg/kg/day; orally) (Rats)

6009- CGA,    Chlorogenic Acid: An In-Depth Review of Its Effectiveness in Cancer Treatment
- Review, Var, NA
TumCCA↑, CGA exerts potent anticancer effects through immunomodulation, induction of programmed cell death (PCD), cell cycle regulation, inhibition of tumor invasion and metastasis, suppression of angiogenesis, modulation of oxidative stress,
TumCI↓,
TumMeta↓,
angioG↓,
ROS↑, CGA exerts pro-oxidant effects within tumor cells in a concentration-dependent manner.
ChemoSen↑, and enhancement of chemotherapy efficacy. Boosting Chemotherapy Effectiveness of CGA
BioAv↓, its clinical applicability is often limited by its pharmacokinetic properties, including poor lipophilicity, low permeability, short half-life, and low oral bioavailability.
Half-Life↓,
PI3K↓, CGA suppresses the PI3K/Akt/mTOR cascade, increasing the Bax/Bcl-2 ratio and triggering apoptosis
Akt↓,
mTOR↓,
Apoptosis↑,
NOTCH↓, In non–small-cell lung cancer, it suppresses Notch pathway activity to induce apoptosis
Hif1a↓, CGA inhibits angiogenesis both in vitro and in vivo by suppressing HIF-1α expression and Akt phosphorylation, leading to reduced VEGF secretion
VEGF↓,
Casp3↑, In leukemia cells (U937, CML), CGA triggers caspase-3 activation, mitochondrial depolarization, and Bcr-Abl phosphorylation downregulation, culminating in apoptosis
MMP↓,
Ferroptosis↑, enhance bioavailability and sustain ROS generation, promoting ferroptosis in lymphoma and other malignancies [
ATP↓, combination of caffeine and CGA regulates mitochondrial function and ATP production, specifically targeting breast cancer mitochondria.

3861- CUR,    Curcumin as a novel therapeutic candidate for cancer: can this natural compound revolutionize cancer treatment?
- Review, Var, NA
*antiOx↑, fig 1
*Inflam↓,
PI3K↓, By inhibiting pro-survival and pro-inflammatory signaling cascades such as PI3K/Akt/mTOR, MAPK, Wnt/β-catenin, NF-κB, Hedgehog, Notch, and JAK/STAT3, curcumin effectively impedes cancer cell growth and promotes apoptosis.
Akt↓,
mTOR↓,
Wnt↓,
β-catenin/ZEB1↓,
NF-kB↓,
HH↓,
NOTCH↓,
JAK↓,
STAT3↓,
ADAM10↓, Curcumin may inhibit the function of the Notch pathway in cancer by inhibiting Notch pathway activators such as gamma secretases, Notch ligands, or ADAM10.

4671- CUR,    Targeting colorectal cancer stem cells using curcumin and curcumin analogues: insights into the mechanism of the therapeutic efficacy
- in-vitro, CRC, NA
CSCs↓, Intriguingly, curcumin and its analogues have also recently been shown to be effective in lowering tumour recurrence by targeting the CSC population, hence inhibiting tumour growth.
TumCG↓,
ChemoSen↑, curcumin could play a role as chemosensitiser whereby the colorectal CSCs are now sensitised towards the anti-cancer therapy,
Wnt↓, Three major signaling pathways in which curcumin plays a pivotal role in CSC self-renewal behavior are the Wnt/β-catenin, Sonic Hedgehog (SHH), and Notch pathways
β-catenin/ZEB1↓,
Shh↓,
NOTCH↓,
DNMT1↓, Figure 1
STAT3↓,
NF-kB↓,
EGFR↓,
IGFR↓,
TumCCA↓,
cl‑PARP↑,
BAX↑,
ECM/TCF↓,

1607- EA,    Exploring the Potential of Ellagic Acid in Gastrointestinal Cancer Prevention: Recent Advances and Future Directions
- Review, GC, NA
STAT3↓, EA inhibits STAT3 signaling
TumCP↓, EA inhibits cell proliferation, induces apoptosis
Apoptosis↑,
NF-kB↓, inhibiting nuclear factor-kappa B
EMT↓, suppressing epithelial–mesenchymal transition
RadioS↑, In liver cancer, EA exhibits radio-sensitizing effects
antiOx↑, As a potential antioxidant agent,
COX1↓, EA suppresses the expression of several factors, including COX1, COX2, c-myc, snail, and twist1
COX2↓,
cMyc↓,
Snail↓,
Twist↓,
MMP2↓, significantly decreased MMP-2 and MMP-9 expression and activity.
P90RSK↓,
CDK8↓, downregulate CDK8 expression and activity
PI3K↓, inactivating PI3K/Akt signaling
Akt↓,
TumCCA↑, promote cell cycle arrest
Casp8↑, ctivating caspase-8, and lowering proliferating cell nuclear antigen (PCNA) expression,
PCNA↓,
TGF-β↓,
Shh↓, suppression of the Akt, Shh, and Notch pathways, EA can prevent the growth, angiogenesis, and metastasis of pancreatic cancer
NOTCH↓,
IL6↓,
ALAT↓, decreasing liver injury biomarkers such as alanine transaminase (ALT), alkaline phosphatase (ALP), and aspartate aminotransferase (AST)
ALP↓,
AST↓,
VEGF↓,
P21↑,
*toxicity∅, no toxicity was found for a 50% effective dose by the intraperitoneal route inferior to 1 mg/kg/day
*Inflam↓, ncluding anti-inflammatory [10], anti-oxidant [11], anti-allergic [12], and anti-mutagenic [13] properties, as well as potential health advantages like gastroprotective [14], cardioprotective [15], neuroprotective [16, 17], and hepatoprotective [18,
*cardioP↑,
*neuroP↑,
*hepatoP↑,
ROS↑, Exposure to EAs induced apoptosis, accelerated cell cycle arrest, and elevated the generation of reactive oxygen intermediates [59].
*NRF2↓, As a potential antioxidant agent, it scavenges reactive oxygen species (ROS), and by upregulating of Nrf2,
*GSH↑, Moreover, EA increases reduced glutathione (GSH), which is critical for cellular defense against oxidative stress and liver damage,

1605- EA,    Ellagic Acid and Cancer Hallmarks: Insights from Experimental Evidence
- Review, Var, NA
*BioAv↓, Within the gastrointestinal tract, EA has restricted bioavailability, primarily due to its hydrophobic nature and very low water solubility.
antiOx↓, strong antioxidant properties [12,13], anti-inflammatory effects
Inflam↓,
TumCP↓, numerous studies indicate that EA possesses properties that can inhibit cell proliferation
TumCCA↑, achieved this by causing cell cycle arrest at the G1 phase
cycD1/CCND1↓, reduction of cyclin D1 and E levels, as well as to the upregulation of p53 and p21 proteins
cycE/CCNE↓,
P53↑,
P21↑,
COX2↓, notable reduction in the protein expression of COX-2 and NF-κB as a result of this treatment
NF-kB↓,
Akt↑, suppressing Akt and Notch signaling pathways
NOTCH↓,
CDK2↓,
CDK6↓,
JAK↓, suppression of the JAK/STAT3 pathway
STAT3↓,
EGFR↓, decreased expression of epidermal growth factor receptor (EGFR)
p‑ERK↓, downregulated the expression of phosphorylated ERK1/2, AKT, and STAT3
p‑Akt↓,
p‑STAT3↓,
TGF-β↓, downregulation of the TGF-β/Smad3
SMAD3↓,
CDK6↓, EA demonstrated the capacity to bind to CDK6 and effectively inhibit its activity
Wnt/(β-catenin)↓, ability of EA to inhibit phosphorylation of EGFR
Myc↓, Myc, cyclin D1, and survivin, exhibited decreased levels
survivin↓,
CDK8↓, diminished CDK8 level
PKCδ↓, EA has demonstrated a notable downregulatory impact on the expression of classical isoenzymes of the PKC family (PKCα, PKCβ, and PKCγ).
tumCV↓, EA decreased cell viability
RadioS↑, further intensified when EA was combined with gamma irradiation.
eff↑, EA additionally potentiated the impact of quercetin in promoting the phosphorylation of p53 at Ser 15 and increasing p21 protein levels in the human leukemia cell line (MOLT-4)
MDM2↓, finding points to the ability of reduced MDM2 levels
XIAP↓, downregulation of X-linked inhibitor of apoptosis protein (XIAP).
p‑RB1↓, EA exerted a decrease in phosphorylation of pRB
PTEN↑, EA enhances the protein phosphatase activity of PTEN in melanoma cells (B16F10)
p‑FAK↓, reduced phosphorylation of focal adhesion kinase (FAK)
Bax:Bcl2↑, EA significantly increases the Bax/Bcl-2 rati
Bcl-xL↓, downregulates Bcl-xL and Mcl-1
Mcl-1↓,
PUMA↑, EA also increases the expression of Bcl-2 inhibitory proapoptotic proteins PUMA and Noxa in prostate cancer cells
NOXA↑,
MMP↓, addition to the reduction in MMP, the release of cytochrome c into the cytosol occurs in pancreatic cancer cells
Cyt‑c↑,
ROS↑, induction of ROS production
Ca+2↝, changes in intracellular calcium concentration, leading to increased levels of EndoG, Smac/DIABLO, AIF, cytochrome c, and APAF1 in the cytosol
Endoglin↑,
Diablo↑,
AIF↑,
iNOS↓, decreased expression of Bcl-2, NF-кB, and iNOS were observed after exposure to EA at concentrations of 15 and 30 µg/mL
Casp9↑, increase in caspase 9 activity in EA-treated pancreatic cancer cells PANC-1
Casp3↑, EA-induced caspase 3 activation and PARP cleavage in a dose-dependent manner (10–100 µmol/L)
cl‑PARP↑,
RadioS↑, EA sensitizes and reduces the resistance of breast cancer MCF-7 cells to apoptosis induced by γ-radiation
Hif1a↓, EA reduced the expression of HIF-1α
HO-1↓, EA significantly reduced the levels of two isoforms of this enzyme, HO-1, and HO-2, and increased the levels of sEH (Soluble epoxide hydrolase) in LnCap
HO-2↓,
SIRT1↓, EA-induced apoptosis was associated with reduced expression of HuR and Sirt1
selectivity↑, A significant advantage of EA as a potential chemopreventive, anti-tumor, or adjuvant therapeutic agent in cancer treatment is its relative selectivity
Dose∅, EA significantly reduced the viability of cancer cells at a concentration of 10 µmol/L, while in healthy cells, this effect was observed only at a concentration of 200 µmol/L
NHE1↓, EA had the capacity to regulate cytosolic pH by downregulating the expression of the Na+/H+ exchanger (NHE1)
Glycolysis↓, led to intracellular acidification with subsequent impairment of glycolysis
GlucoseCon↓, associated with a decrease in the cellular uptake of glucose
lactateProd↓, notable reduction in lactate levels in supernatant
PDK1?, inhibit pyruvate dehydrogenase kinase (PDK) -bind and inhibit PDK3
PDK1?,
ECAR↝, EA has been shown to influence extracellular acidosis
COX1↓, downregulation of cancer-related genes, including COX1, COX2, snail, twist1, and c-Myc.
Snail↓,
Twist↓,
cMyc↓,
Telomerase↓, EA, might dose-dependently inhibit telomerase activity
angioG↓, EA may inhibit angiogenesis
MMP2↓, EA demonstrated a notable reduction in the secretion of matrix metalloproteinase (MMP)-2 and MMP-9.
MMP9↓,
VEGF↓, At lower concentrations (10 and 20 μM), EA led to a substantial increase in VEGF levels. However, at higher doses (40 and 100 μM), a notable reduction in VEGF
Dose↝, At lower concentrations (10 and 20 μM), EA led to a substantial increase in VEGF levels. However, at higher doses (40 and 100 μM), a notable reduction in VEGF
PD-L1↓, EA downregulated the expression of the immune checkpoint PD-L1 in tumor cells
eff↑, EA might potentially enhance the efficacy of anti-PD-L1 treatment
SIRT6↑, EA exhibited statistically significant upregulation of sirtuin 6 at the protein level in Caco2 cells
DNAdam↓, increase in DNA damage

1621- EA,    The multifaceted mechanisms of ellagic acid in the treatment of tumors: State-of-the-art
- Review, Var, NA
AntiCan↑, Studies have shown its anti-tumor effect in gastric cancer, liver cancer, pancreatic cancer, breast cancer, colorectal cancer, lung cancer and other malignant tumors
Apoptosis↑,
TumCP↓,
TumMeta↓,
TumCI↓,
TumAuto↑,
VEGFR2↓, inhibition of VEGFR-2 signaling
MAPK↓, MAPK and PI3K/Akt pathways
PI3K↓,
Akt↓,
PD-1↓, Downregulation of VEGFR-2 and PD-1 expression
NOTCH↓, Inhibition of Akt and Notch
PCNA↓, regulation of the expression of proliferation-related proteins PCNA, Ki67, CyclinD1, CDK-2, and CDK-6
Ki-67↓,
cycD1/CCND1↓,
CDK2↑,
CDK6↓,
Bcl-2↓,
cl‑PARP↑, up-regulated the expression of cleaved PARP, Bax, Active Caspase3, DR4, and DR5
BAX↑,
Casp3↑,
DR4↑,
DR5↑,
Snail↓, down-regulated the expression of Snail, MMP-2, and MMP-9
MMP2↓,
MMP9↓,
TGF-β↑, up-regulation of TGF-β1
PKCδ↓, Inhibition of PKC signaling
β-catenin/ZEB1↓, decreases the expression level of β-catenin
SIRT1↓, down-regulates the expression of anti-apoptotic protein, SIRT1, HuR, and HO-1 protein
HO-1↓,
ROS↑, up-regulates ROS
CHOP↑, activating the CHOP signaling pathway to induce apoptosis
Cyt‑c↑, releases cytochrome c
MMP↓, decreases mitochondrial membrane potential and oxygen consumption,
OCR↓,
AMPK↑, activates AMPK, and downregulates HIF-1α expression
Hif1a↓,
NF-kB↓, inhibition of NF-κB pathway
E-cadherin↑, Upregulates E-cadherin, downregulates vimentin and then blocks EMT progression
Vim↓,
EMT↓,
LC3II↑, Up-regulation of LC3 – II expression and down-regulation of CIP2A
CIP2A↓,
GLUT1↓, regulation of glycolysis-related gene GLUT1 and downstream protein PDH expression
PDH↝,
MAD↓, Downregulation of MAD, LDH, GR, GST, and GSH-Px related protein expressio
LDH↓,
GSTs↑,
NOTCH↓, inhibited the expression of Akt and Notch protein
survivin↓, survivin and XIAP was also significantly down-regulated
XIAP↓,
ER Stress↑, through ER stress
ChemoSideEff↓, could improve cisplatin-induced hepatotoxicity in colorectal cancer cells
ChemoSen↑, Enhancing chemosensitivity

651- EGCG,    Epigallocatechin-3-Gallate Therapeutic Potential in Cancer: Mechanism of Action and Clinical Implications
ROS↑, mounting evidence that EGCG can stimulate ROS production, which in turn leads to the phosphorylation and activation of AMPK
p‑AMPK↑,
mTOR↓,
FAK↓,
Smo↓,
Gli1↓,
HH↓,
TumCMig↓,
TumCI↓,
NOTCH↓,
JAK↓,
STAT↓,
Bcl-2↓,
Bcl-xL↓,
BAX↑,
Casp9↑,

4635- HT,    Hydroxytyrosol, a Component of Olive Oil for Breast Cancer Prevention in Women at High Risk of Cancer
- Trial, BC, NA
*Wnt↓, Wnt Signaling Pathway Downregulated by HT
*NOTCH↓, Notch Signaling Pathway Downregulated by HT
*ROS↓, Oxidative Stress–Induced Senescence Pathway Downregulated by HT
TumCP↓, Cell Proliferation Signaling Significantly Downregulated After HT
CSCs↓, Our study demonstrates that a natural antioxidant compound can decrease the signaling in CSC pathways such as WNT and enhance DNA damage repair.

2916- LT,    Antioxidative and Anticancer Potential of Luteolin: A Comprehensive Approach Against Wide Range of Human Malignancies
- Review, Var, NA - Review, AD, NA - Review, Park, NA
proCasp9↓, , by inactivating proteins; such as procaspase‐9, CDC2 and cyclin B or upregulation of caspase‐9 and caspase‐3, cytochrome C, cyclin A, CDK2, and APAF‐1, in turn inducing cell cycle
CDC2↓,
CycB/CCNB1↓,
Casp9↑,
Casp3↑,
Cyt‑c↑,
cycA1/CCNA1↑,
CDK2↓, inhibit CDK2 activity
APAF1↑,
TumCCA↑,
P53↑, enhances phosphorylation of p53 and expression level of p53‐targeted downstream gene.
BAX↑, Increasing BAX protein expression; decreasing VEGF and Bcl‐2 expression it can initiate cell cycle arrest and apoptosis.
VEGF↓,
Bcl-2↓,
Apoptosis↑,
p‑Akt↓, reduce expression levels of p‐Akt, p‐EGFR, p‐Erk1/2, and p‐STAT3.
p‑EGFR↓,
p‑ERK↓,
p‑STAT3↓,
cardioP↑, Luteolin plays positive role against cardiovascular disorders by improving cardiac function
Catalase↓, It can reduce activity levels of catalase, superoxide dismutase, and GS4
SOD↓,
*BioAv↓, bioavailability of luteolin is very low. Due to the momentous first pass effect, only 4.10% was found to be available from dosage of 50 mg/kg intake of luteolin
*antiOx↑, luteolin classically exhibits antioxidant features
*ROS↓, The antioxidant potential of luteolin and its glycosides is mainly due to scavenging activity against reactive oxygen species (ROS) and nitrogen species
*NO↓,
*GSTs↑, Luteolin may also have a role in protection and enhancement of endogenous antioxidants such as glutathione‐S‐transferase (GST), glutathione reductase (GR), superoxide dismutase (SOD), and catalase (CAT)
*GSR↑,
*SOD↑,
*Catalase↑,
*lipid-P↓, Luteolin supplementation significantly suppressed the lipid peroxidation
PI3K↓, inhibits PI3K/Akt signaling pathway to induce apoptosis
Akt↓,
CDK2↓, inhibit CDK2 activity
BNIP3↑, upregulation of BNIP3 gene
hTERT/TERT↓, Suppress hTERT in MDA‐MB‐231 breast cancer cel
DR5↑, Boost DR5 expression
Beclin-1↑, Activate beclin 1
TNF-α↓, Block TNF‐α, NF‐κB, IL‐1, IL‐6,
NF-kB↓,
IL1↓,
IL6↓,
EMT↓, Suppress EMT essentially notable in cancer metastasis
FAK↓, Block EGFR‐signaling pathway and FAK activity
E-cadherin↑, increasing E‐cadherin expression by inhibiting mdm2
MDM2↓,
NOTCH↓, Inhibit NOTCH signaling
MAPK↑, Activate MAPK to inhibit tumor growt
Vim↓, downregulation of vimentin, N‐cadherin, Snail, and induction of E‐cadherin expressions
N-cadherin↓,
Snail↓,
MMP2↓, negatively regulated MMP2 and TWIST1
Twist↓,
MMP9↓, Inhibit matrix metalloproteinase‐9 expressions;
ROS↑, Induce apoptosis, reactive oxygen development, promotion of mitochondrial autophagy, loss of mitochondrial membrane potential
MMP↓,
*AChE↓, Reduce AchE activity to slow down inception of Alzheimer's disease‐like symptoms
*MMP↑, Reverse mitochondrial membrane potential dissipation
*Aβ↓, Inhibit Aβ25‐35
*neuroP↑, reduces neuronal apoptosis; inhibits Aβ generation
Trx1↑, luteolin against human bladder cancer cell line T24 was due to induction cell‐cycle arrest at G2/M, downregulation of p‐S6, suppression of cell survival, upregulation of p21 and TRX1, reduction in ROS levels.
ROS↓,
*NRF2↑, Luteolin reduced renal injury by inhibiting XO activity, modulating uric acid transporters, as well as activating Nrf2 HO‐1/NQO1 antioxidant pathways and renal SIRT1/6 cascade.
NRF2↓, Luteolin exerted anticancer effects in HT29 cells as it inhibits nuclear factor‐erythroid‐2‐related factor 2 (Nrf2)/antioxidant response element (ARE) signaling pathway
*BBB↑, Luteolin can be used to treat brain cancer due to ability of this molecule to easily cross the blood–brain barrier
ChemoSen↑, In ovarian cancer cells, luteolin chemosensitizes the cells through repressing the epithelial‐mesenchymal transition markers
GutMicro↑, Luteolin was also observed to modulate gut microbiota which reduce the number of tumors in case of colorectal cancer by enhancing the number of health‐related microbiota and reduced the microbiota related to inflammation

1803- NarG,    Naringin and naringenin as anticancer agents and adjuvants in cancer combination therapy: Efficacy and molecular mechanisms of action, a comprehensive narrative review
- Review, Var, NA
JAK↓,
STAT↓,
PI3K↓,
Akt↓,
mTOR↓,
NF-kB↓,
COX2↓,
NOTCH↓,
TumCCA↑,

1271- NCL,    Niclosamide inhibits ovarian carcinoma growth by interrupting cellular bioenergetics
- vitro+vivo, Ovarian, SKOV3
Wnt/(β-catenin)↓,
mTOR↓,
STAT3↓,
NF-kB↓,
NOTCH↓,
TumCG↓,
Apoptosis↑,
MEK↓, inactivating MEK1/2-ERK1/2
ERK↓,
mitResp↓,
Glycolysis↓, aerobic glycolysis
ROS↑, abolishment of the excess ROS production with NAC (10 mM) abrogated the Niclosamide-induced cell apoptosis under glucose deprivation
JNK↑,

5253- NCL,    Niclosamide: Beyond an antihelminthic drug
- Review, Var, NA
TumCP↓, Niclosamide was found to inhibit adrenocortical carcinoma cellular proliferation, which was associated with apoptosis, reduction of epithelial-to-mesenchymal transition and β-catenin levels.
Apoptosis↑,
EMT↓,
β-catenin/ZEB1↓,
TumCG↓, Oral administration of niclosamide led to tumor growth inhibition with no observed toxicity.
toxicity↓,
Wnt↓, Lu et al. reported that niclosamide inhibits Wnt/β-catenin signaling by promoting Wnt co-receptor LRP6 degradation in breast cancer cells [11].
LRP6↓,
eff↑, niclosamide acts synergistically with a monoclonal antibody that specifically activates TRAIL death receptor 5 to inhibit tumor growth of basal-like breast cancers [12].
DR5↑,
mTORC1↓,
pH↓, Niclosamide lowered the cytoplasmic pH and may indirectly lead to inhibition of mTORC1 signaling [13]
CSCs↓, Niclosamide also was found to prevent the conversion of non-breast cancer stem cells into cancer stem cells
IL6↓, This mechanism is associated with inhibition of the IL6-JAK1-STAT3 signal transduction pathway
JAK1↓,
STAT3↓, Ren et al. identified niclosamide as a potent STAT3 inhibitor able to suppress STAT3 transcriptional activity
ChemoSen↑, niclosamide alone or in combination with cisplatin represses the growth of xenografts of cisplatin-resistant triple-negative breast cancer cells.
TumCG↓, Niclosamide inhibited growth of colon cancer cells from human patients both in vitro and in vivo, regardless of mutations in APC [24].
tumCV↓, niclosamide selectively inhibited glioblastoma cell viability [29]. Detailed mechanism studies revealed that niclosamide suppressed the Wnt, Notch, mTOR, and NF-κB signaling pathways.
NOTCH↓,
NF-kB↓,
EGFR↓, Li et al. reported that inhibition of EGFR by erlotinib, an FDA-approved therapeutic agent, led to activation of STAT3 signaling in head and neck cancer cells
ROS↑, niclosamide inhibits TNF-α-induced NF-κB–dependent reporter activity and increased the levels of reactive oxygen species (ROS) in AML cells.
RadioS↑, niclosamide enhanced radiosensitivity of the non-small cell lung cancer cell line H1299.
cFos↓, inhibit osteosarcoma cell proliferation, migration, and survival. This inhibitory effect is associated with decreased expression of c-Fos, c-Jun. E2F1, and c-Myc.
cJun↓,
E2Fs↓,
cMyc↓,
Half-Life↓, Niclosamide exhibits a short half-life (6.0 ± 0.8 h). Niclosamide was rapidly absorbed with a Tmax of less than 30 min. The Cmax is 354 ± 152 ng/mL.
BioAv↝, AUC and bioavailability were 429 ± 100 and 10%, respectively. In order to make more effective use of niclosamide, additional work needs to be done to improve its solubility, absorption and systemic bioavailability.

5254- NCL,    The magic bullet: Niclosamide
- Review, Var, NA
Wnt↓, In particular, niclosamide inhibits multiple oncogenic pathways such as Wnt/β-catenin, Ras, Stat3, Notch, E2F-Myc, NF-κB, and mTOR and activates tumor suppressor signaling pathways such as p53, PP2A, and AMPK.
β-catenin/ZEB1↓,
RAS↓,
STAT3↓,
NOTCH↓,
E2Fs↓,
mTOR↓,
eff↑, Moreover, niclosamide potentially improves immunotherapy by modulating pathways such as PD-1/PDL-1.
PD-1↓,
PD-L1↓, primarily through PD-L1 ligand downregulation in cancer cells.
BioAv↝, The original pharmacokinetics study showed that the maximal serum concentration can reach 0.25-6.0ug/ml (0.76-18.34 µM) following administration of a single 2g dose (11).
toxicity↓, a strong safety profile and tolerability in humans.
BioAv↑, A potential solution to the aforementioned challenge is niclosamide ethanolamine (NEN), a salt form of niclosamide that also functions as a mitochondrial uncoupler with a superior safety profile and enhanced bioavailability
ETC↑, NEN activates the ETC to boost NADH oxidation, thereby leading to an increased intracellular NAD+/NADH ratio and driving the TCA cycle forward.
NADH:NAD↓,
TCA↑,
Warburg↓, leading to a reversal of the Warburg effect and the induction of cellular differentiation
Diff↑,
AMPK↑, figure 3
P53↑,
PP2A↑,
HIF-1↓,
KRAS↓,
Myc↓,
RadioS↑, leading to a reversal of the Warburg effect and the induction of cellular differentiation
ChemoSen↑, Niclosamide has shown synergistic anti-tumor effects with a broad spectrum of chemotherapy drugs.
Dose↝, In this trial, either 500mg or 1000mg niclosamide was given three times daily to patients. However, the maximal plasma concentration ranged from 35.7–82 ng/mL (0.1µM-0.25 µM), a range that failed to be consistently above the minimum effective concent
Dose↑, In contrast, the ongoing clinical trial NCT02807805 is administering 1200 mg of reformulated orally bioavailable niclosamide orally (PO) three times daily to patients, resulting in 0.21µM-0.723 plasma niclosamide concentrations exceeding the therape

4968- PSO,    Psoralidin: emerging biological activities of therapeutic benefits and its potential utility in cervical cancer
- in-vitro, Cerv, NA
*Inflam↓, showing anti-inflammatory, anti-oxidant, estrogenic, neuroprotective, anti-diabetic, anti-depressant, antimicrobial, and anti-tumor activities substantiate its promising biological effects.
*antiOx↑,
*neuroP↑,
*AntiDiabetic↑,
*Bacteria↓,
AntiTum↑,
CSCs↓, Its capacity to effectively target cancer stem cells (CSCs) in general adds to its therapeutic potential.
ROS↑, Psoralidin carries out its anti-cancer activity by inducing oxidative stress, autophagy, and apoptosis.
TumAuto↑,
Apoptosis↑,
ChemoSen↑, This unique characteristic suggests its potential to be used as an adjunct molecule in combination with existing treatment to enhance the efficacy of chemo/radiotherapy for treating CaCx.
RadioS↑,
BioAv↓, low bioavailability and intestinal efflux limit the use of psoralidin in clinical applications
*cardioP↑, Psoralidin demonstrated cardioprotective effects.
*ROS↓, Furthermore, psoralidin administration resulted in a decrease in ROS levels and lactate dehydrogenase (LDH) release, indicating reduced oxidative stress and cellular damage in the heart.
*LDH↓,
TumCP↓, LNCaP Induction of apoptosis ↓Cell proliferation ↑TRAIL
TRAIL⇅,
TumCMig↓, PC-3, PzHPV-7, C4-2B 5–20 µM ↓Cell proliferation, ↓Migration, Invasion ROS generation
EMT↓, RWPE-1, xenograft mice 4 µM ↓Cell proliferation, Induction of apoptosis, Autophagy induction, EMT Inhibition ↓NF-кB signaling
NF-kB↓,
P53↑, HepG2 64 µM Induction of apoptosis ↑p53
Casp3↑, figure 4
NOTCH↓,
CSCs↓, Anti-CSC activity
angioG↓, Anti-angiogenesis
VEGF↓, it inhibited angiogenesis by downregulating the expression of pro-angiogenic molecules VEGF, Ki67, and CD31
Ki-67↓,
CD31↓,
TRAILR↑, psoralidin treatment induced the activation of death receptors 1 (DR 1) and DR 2 after 48 h of treatment
MMP↓, Psoralidin significantly increased the loss of ΔΨm, affecting a large percentage of cancer cells (58.38% ± 1.41%) and causing a major disruption of the mitochondrial membrane potential.
BioAv↓, hydrophobic nature, inadequate pharmacokinetic profile of psoralidin, and intestinal efflux, which hampers its clinical application
BioAv↑, bioavailability of psoralidin significantly improved with a value of 339% w.r.t to reference through its nanoencapsulation (NCs) using chitosan and Eudragit S100

4701- PTS,  RES,    Targeting cancer stem cells and signaling pathways by resveratrol and pterostilbene
- Review, Var, NA
CSCs↓, Resveratrol and pterostilbene target CSCs
E-cadherin↑, " E-cadherin, # NF-jB, # EMT-associated molecules (Twist1,vimentin)
NF-kB↓,
EMT↓,
GRP78/BiP↓, GRP78
CD133↓, CD133
COX2↓, COX-2,
β-catenin/ZEB1↓,
NOTCH↓, Notch

3360- QC,    Role of Flavonoids as Epigenetic Modulators in Cancer Prevention and Therapy
- Review, Var, NA
HDAC↓, Quercetin modulates the expression of various chromatin modifiers and declines the activity of HDACs, DNMTs and HMTs in a dose-dependent manner in human cervical cancer (HeLa) cells
DNMTs↓,
HMTs↓,
Let-7↑, Quercetin also induced let-7c which decreased pancreatic tumor growth by posttranscriptional activation of Numbl and indirect inhibition of Notch
NOTCH↓,

3369- QC,    Pharmacological basis and new insights of quercetin action in respect to its anti-cancer effects
- Review, Pca, NA
FAK↓, Quercetin can inhibit HGF-induced melanoma cell migration by inhibiting the activation of c-Met and its downstream Gabl, FAK and PAK [84]
TumCCA↑, stimulation of cell cycle arrest at the G1 stage
p‑pRB↓, mediated through regulation of p21 CDK inhibitor and suppression of pRb phosphorylation resulting in E2F1 sequestering.
CDK2↑, low dose of quercetin has brought minor DNA injury and Chk2 induction
CycB/CCNB1↓, quercetin has a role in the reduction of cyclin B1 and CDK1 levels,
CDK1↓,
EMT↓, quercetin suppresses epithelial to mesenchymal transition (EMT) and cell proliferation through modulation of Sonic Hedgehog signaling pathway
PI3K↓, quercetin on other pathways such as PI3K, MAPK and WNT pathways have also been validated in cervical cancer
MAPK↓,
Wnt↓,
ROS↑, colorectal cancer, quercetin has been shown to suppress carcinogenesis through various mechanisms including affecting cell proliferation, production of reactive oxygen species and expression of miR-21
miR-21↑,
Akt↓, Figure 1 anti-cancer mechanisms
NF-kB↓,
FasL↑,
Bak↑,
BAX↑,
Bcl-2↓,
Casp3↓,
Casp9↑,
P53↑,
p38↑,
MAPK↑,
Cyt‑c↑,
PARP↓,
CHOP↑,
ROS↓,
LDH↑,
GRP78/BiP↑,
ERK↑,
MDA↓,
SOD↑,
GSH↑,
NRF2↑,
VEGF↓,
PDGF↓,
EGF↓,
FGF↓,
TNF-α↓,
TGF-β↓,
VEGFR2↓,
EGFR↓,
FGFR1↓,
mTOR↓,
cMyc↓,
MMPs↓,
LC3B-II↑,
Beclin-1↑,
IL1β↓,
CRP↓,
IL10↓,
COX2↓,
IL6↓,
TLR4↓,
Shh↓,
HER2/EBBR2↓,
NOTCH↓,
DR5↑, quercetin has enhanced DR5 expression in prostate cancer cells
HSP70/HSPA5↓, Quercetin has also suppressed the upsurge of hsp70 expression in prostate cancer cells following heat treatment and enhanced the quantity of subG1 cells
CSCs↓, Quercetin could also suppress cancer stem cell attributes and metastatic aptitude of isolated prostate cancer cells through modulating JNK signaling pathway
angioG↓, Quercetin inhibits angiogenesis-mediated of human prostate cancer cells through negatively modulating angiogenic factors (TGF-β, VEGF, PDGF, EGF, bFGF, Ang-1, Ang-2, MMP-2, and MMP-9)
MMP2↓,
MMP9↓,
IGFBP3↑, Quercetin via increasing the level of IGFBP-3 could induce apoptosis in PC-3 cells
uPA↓, Quercetin through decreasing uPA and uPAR expression and suppressing cell survival protein and Ras/Raf signaling molecules could decrease prostate cancer progression
uPAR↓,
RAS↓,
Raf↓,
TSP-1↑, Quercetin through TSP-1 enhancement could effectively inhibit angiogenesis

4667- RES,  CUR,  SFN,    Physiological modulation of cancer stem cells by natural compounds: Insights from preclinical models
- Review, Var, NA
CSCs↓, phytochemicals such as resveratrol, curcumin, sulforaphane, and others suppress CSC-associated pathways as well as sensitize CSCs to chemotherapy and radiotherapy
ChemoSen↑,
RadioS↑,
ALDH↓, deplete ALDH+ or CD44+ CSC pools, which ultimately decrease tumor initiation and recurrence.
CD44↓,
Wnt↓, graphical abstract
β-catenin/ZEB1↓,
NOTCH↓,
HH↓,
NF-kB↓,

4663- RES,    Exploring resveratrol’s inhibitory potential on lung cancer stem cells: a scoping review of mechanistic pathways across cancer models
- Review, Var, NA
*antiOx↑, Resveratrol is a natural compound with notable health benefits, such as anti-inflammatory, antioxidant, and chemopreventive properties.
*Inflam↓,
*chemoPv↑,
CSCs↓, It has shown potential in inhibiting tumorigenesis and tumour progression via targeted therapy, specifically by targeting cancer stem cells (CSCs)
Wnt↓, Three papers reported on the effects on resveratrol on Wnt/ β-catenin pathway
β-catenin/ZEB1↓,
NOTCH↓, 3 papers on Notch pathway
PI3K↓, 3 papers on PI3K/Akt/mTOR pathway
Akt↓,
mTOR↓,
GSK‐3β↝, Akt/GSK β/snail pathway
Snail↓,
HH↓, 4 papers on Hedgehog pathway
p‑GSK‐3β↓, It downregulated p-AKT, p-GSK3β, Snail and N-cadherin in a dose-dependent manner, indicating its role in modulating the Akt/GSK3β/snail signalling pathway to reverse EMT
N-cadherin↓,
EMT↓,
CD133↓, This further reduced CSC markers CD133, CD44, ALDH1A1, OCT4, SOX2 and β-catenin
CD44↓,
ALDH1A1↓,
OCT4↓,
SOX4↓,
Shh↓, Sun et al., reported that resveratrol downregulated SHH, SMO, Gli1 and Gli2 proteins on renal CSC, reducing the number and size of renal cancer cell spheres and decreasing expression of stemness markers CD44 and CD133
Smo↓,
Gli1↓,
GLI2↓,

1730- SFN,    Sulforaphane: An emergent anti-cancer stem cell agent
- Review, Var, NA
BioAv↓, When exposed to high temperatures during meal preparation, myrosinase can be degraded, lose its function, and subsequently compromise the synthesis of SFN.
BioAv↑, eating raw cruciferous vegetables, instead of heating them can significantly improve the biodisponibility of SFN and its subsequent beneficial effects.
GSTA1↑, induction of Phase II enzymes [glutathione S-transferase (GST)
P450↓, (cytochrome P450, CYP) inhibition
TumCCA↑, herb-derived agent can also promote cell cycle arrest and apoptosis by regulating different signaling pathways including Nuclear Factor erythroid Related Factor 2 (Nrf2)-Keap1 and NF-κB.
HDAC↓, modulate the activity of some epigenetic factors, such as histone deacetylases (HDAC),
P21↑, upregulation of p21 and p27,
p27↑,
DNMT1↓, SFN was able to decrease the expression of DNMT1 and DNMT3 in LnCap prostate cancer cells
DNMT3A↓,
cycD1/CCND1↑, reduce methylation in Cyclin D2 promoter, thus inducing Cyclin D2 gene expression in those cells
DNAdam↑, SFN induced DNA damage, enhanced Bax expression and the release of cytochrome C followed by apoptosis
BAX↑,
Cyt‑c↑,
Apoptosis↑,
ROS↑, SFN increased reactive oxygen species (ROS), apoptosis-inducing factor (AIF)
AIF↑,
CDK1↑,
Casp3↑, activation of caspase-3, -8, and -9
Casp8↑,
Casp9↑,
NRF2↑, SFN significantly activated the major antioxidant marker Nrf2 and decreased NFκB, TNF-α, IL-1β
NF-kB↓,
TNF-α↓,
IL1β↓,
CSCs↓, SFN, have attracted attention due to their anti-CSC effect
CD133↓,
CD44↓,
ALDH↓,
Nanog↓,
OCT4↓,
hTERT/TERT↓,
MMP2↓,
EMT↓, SFN was reported to inhibit EMT and metastasis in the NSCLC, the cell lines H1299
ALDH1A1↓, ALDH1A1), Wnt3, and Notch4, other CSC-related genes inhibited by SFN treatment
Wnt↓,
NOTCH↓, SFN can inhibit aberrantly activated embryonic pathways in CSCs, including Sonic Hedgehog (SHH), Wnt/β-catenin, Cripto-1 (CR-1), and Notch.
ChemoSen↑, These results suggest that the antioxidant properties of SFN do not impact the cytotoxicity of antineoplastic drugs, but on the contrary, seems to improve it.
*Ki-67↓, Ki-67 and HDAC3 levels significantly decreased in benign breast tissues, and there was also a reduction in HDAC activity in blood cells
*HDAC3↓,
*HDAC↓,

3282- SIL,    Role of Silymarin in Cancer Treatment: Facts, Hypotheses, and Questions
- Review, NA, NA
hepatoP↑, This group of flavonoids has been extensively studied and they have been used as hepato-protective substances
AntiCan↑, however, silymarin compounds have clear anticancer effects
TumCMig↓, decreasing migration through multiple targeting, decreasing hypoxia inducible factor-1α expression, i
Hif1a↓, In prostate cancer cells silibinin inhibited HIF-1α translation
selectivity↑, antitumoral activity of silymarin compounds is limited to malignant cells while the nonmalignant cells seem not to be affected
toxicity∅, long history of silymarin use in human diseases without toxicity after prolonged administration.
*antiOx↑, as an antioxidant, by scavenging prooxidant free radicals
*Inflam↓, antiinflammatory effects similar to those of indomethacin,
TumCCA↑, MDA-MB 486 breast cancer cells, G1 arrest was found due to increased p21 and decreased CDKs activity
P21↑,
CDK4↓,
NF-kB↓, human prostate carcinoma cells, silymarin decreased ligand binding to Erb1 135 and NF-kB expression was strongly inhibited by silymarin in hepatoma cell
ERK↓, human prostate carcinoma cells, silymarin decreased ligand binding to Erb1 135 and NF-kB expression was strongly inhibited by silymarin in hepatoma cell
PSA↓, Treating prostate carcinoma cells with silymarin the levels of PSA were significantly decreased and cell growth was inhibited through decreased CDK activity and induction of Cip1/p21 and Kip1/p27. 1
TumCG↓,
p27↑,
COX2↓, such as anti-COX2 and anti-IL-1α activity, 140 antiangiogenic effects through inhibition of VEGF secretion, upregulation of Insulin like Growth Factor Binding Protein 3 (IGFBP3), 141 and inhibition of androgen receptors.
IL1↓,
VEGF↓,
IGFBP3↑,
AR↓,
STAT3↓, downregulation of the STAT3 pathway which was seen in many cell models.
Telomerase↓, silymarin has the ability to decrease telomerase activity in prostate cancer cells
Cyt‑c↑, mitochondrial cytochrome C release-caspase activation.
Casp↑,
eff↝, Malignant p53 negative cells show only minimal apoptosis when treated with silymarin. Therefore, one conclusion is that silymarin may be useful in tumors with conserved p53.
HDAC↓, inhibit histone deacetylase activity;
HATs↑, increase histone acetyltransferase activity
Zeb1↓, reduce expression of the transcription factor ZEB1
E-cadherin↑, increase expression of E-cadherin;
miR-203↑, increase expression of miR-203
NHE1↓, reduce activation of sodium hydrogen isoform 1 exchanger (NHE1)
MMP2↓, target β catenin and reduce the levels of MMP2 and MMP9
MMP9↓,
PGE2↓, reduce activation of prostaglandin E2
Vim↓, suppress vimentin expression
Wnt↓, inhibit Wnt signaling
angioG↓, Silymarin inhibits angiogenesis.
VEGF↓, VEGF downregulation
*TIMP1↓, Silymarin has the capacity to decrease TIMP1 expression166–168 in mice.
EMT↓, found that silibinin had no effect on EMT. However, the opposite was found in other malignant tissues160–162 where it showed inhibitory effects.
TGF-β↓, Silibinin reduces the expression of TGF β2 in different tumors such as triple negative breast, 174 prostate, and colorectal cancers.
CD44↓, Silibinin decreased CD44 expression and the activation of EGFR (epidermal growth factor receptor)
EGFR↓,
PDGF↓, silibinin had the ability to downregulate PDFG in fibroblasts, thus decreasing proliferation.
*IL8↓, Flavonoids, in general, reduce levels of IL-8. Curcumin, 200 apigenin, 201 and silybin showed the ability to decrease IL-8 levels
SREBP1↓, Silymarin inhibited STAT3 phosphorylation and decreased the expression of intranuclear sterol regulatory element binding protein 1 (SREBP1), decreasing lipid synthesis.
MMP↓, reduced membrane potential and ATP content
ATP↓,
uPA↓, silibinin decreased MMP2, MMP9, and urokinase plasminogen activator receptor level (uPAR) in neuroblastoma cells. uPAR is also a marker of cell invasion.
PD-L1↓, Silibinin inhibits PD-L1 by impeding STAT5 binding in NSCLC.
NOTCH↓, Silybin inhibited Notch signaling in hepatocellular carcinoma cells showing antitumoral effects
*SIRT1↑, Silymarin can also increase SIRT1 expression in other tissues, such as hippocampus, 221 articular chondrocytes, 222 and heart muscle
SIRT1↓, Silymarin seems to act differently in tumors: in lung cancer cells SIRT downregulated SIRT1 and exerted multiple antitumor effects such as reduced adhesion and migration and increased apoptosis.
CA↓, Silymarin has the ability to inhibit CA isoforms CA I and CA II.
Ca+2↑, ilymarin increases mitochondrial release of Ca++ and lowers mitochondrial membrane potential in cancer cell
chemoP↑, Silymarin: Decreasing Side Effects and Toxicity of Chemotherapeutic Drugs
cardioP↑, There is also evidence that it protects the heart from doxorubicin toxicity, however, it is less potent than quercetin in this effect.
Dose↝, oral administration of 240 mg of silybin to 6 healthy volunteers the following results were obtained 377 : maximum\,plasmaconcentration0.34±0.16⁢𝜇⁢g/m⁢L
Half-Life↝, and time to maximum plasma concentration 1.32 ± 0.45 h. Absorption half life 0.17 ± 0.09 h, elimination half life 6.32 ± 3.94 h
BioAv↓, silymarin is not soluble in water and oral administration shows poor absorption in the alimentary tract (approximately 1% in rats,
BioAv↓, Our conclusion is that, from a bioavailability standpoint, it is much easier to achieve migration inhibition, than proliferative reduction.
BioAv↓, Combination with succinate: is available on the market under the trade mark Legalon® (bis hemisuccinate silybin). Combination with phosphatidylcholine:
toxicity↝, 13 g daily per os divided into 3 doses was well tolerated. The most frequent adverse event was asymptomatic liver toxicity.
Half-Life↓, It may be necessary to administer 800 mg 4 times a day because the half-life is short.
ROS↓, its ability as an antioxidant reduces ROS production
FAK↓, Silibinin decreased human osteosarcoma cell invasion through Erk inhibition of a FAK/ERK/uPA/MMP2 pathway

2084- TQ,    Thymoquinone, as an anticancer molecule: from basic research to clinical investigation
- Review, Var, NA
*ROS↓, An interesting study reported that thymoquinone is actually a potent apoptosis inducer in cancer cells, but it exerts antiapoptotic effect through attenuating oxidative stress in other types of cell injury
*chemoPv↑, antioxidant activity of thymoquinone is responsible for its chemopreventive activities
ROS↑, other studies reported thymoquinone induce apoptosis in cancer cells by exerting oxidative damage
ROS⇅, Another hypothesis states that thymoquinone acts as an antioxidant at lower concentrations and a prooxidant at higher concentrations
MUC4↓, Torres et al. [17] revealed that thymoquinone down-regulates glycoprotein mucin 4 (MUC4)
selectivity↑, thymoquinone was found to inhibit DNA synthesis, proliferation, and viability of cancerous cells, such as LNCaP, C4-B, DU145, and PC-3, but not noncancerous BPH-1 prostate epithelial cells [20].
AR↓, Down-regulation of androgen receptor (AR) and cell proliferation regulator E2F-1 was indicated as the mechanism behind thymoquinone’s action in prostate cancer
cycD1/CCND1↓, expression of STAT3-regulated gene products, such as cyclin D1, Bcl-2, Bcl-xL, survivin, Mcl-1 and vascular endothelial growth factor (VEGF), was inhibited by thymoquinone, which ultimately increased apoptosis and killed cancer cells
Bcl-2↓,
Bcl-xL↓,
survivin↓,
Mcl-1↓,
VEGF↓,
cl‑PARP↑, induction of the cleavage of poly-(ADP-ribose) polymerase (PARP
ROS↑, In ALL cell line CEM-ss, thymoquinone treatment generated reactive oxygen species (ROS) and HSP70
HSP70/HSPA5↑,
P53↑, thymoquinone can induce apoptosis in MCF-7 breast cancer cells via the up-regulation of p53 expression
miR-34a↑, Thymoquinone significantly increased the expression of miR-34a via p53, and down-regulated Rac1 expression
Rac1↓,
TumCCA↑, In hepatic carcinoma, thymoquinone induced cell cycle arrest and apoptosis by repressing the Notch signaling pathway
NOTCH↓,
NF-kB↓, Evidence revealed that thymoquinone suppresses tumor necrosis factor (TNF-α)-induced NF-kappa B (NF-κB) activation
IκB↓, consequently inhibits the activation of I kappa B alpha (I-κBα) kinase, I-κBα phosphorylation, I-κBα degradation, p65 phosphorylation
p‑p65↓,
IAP1↓, down-regulated the expression of NF-κB -regulated antiapoptotic gene products, like IAP1, IAP2, XIAP Bcl-2, Bcl-xL;
IAP2↑,
XIAP↓,
TNF-α↓, It also inhibited monocyte chemo-attractant protein-1 (MCP-1), TNF-α, interleukin (IL)-1β and COX-2, ultimately reducing the NF-κB activation in pancreatic ductal adenocarcinoma cells
COX2↓,
Inflam↓, indicating its role as an inhibitor of proinflammatory pathways
α-tubulin↓, Without affecting the tubulin levels in normal human fibroblast, thymoquinone induces degradation of α and β tubulin proteins in human astrocytoma U87 cells and in T lymphoblastic leukaemia Jurkat cells, and thus exerts anticancer activity
Twist↓, thymoquinone treatment inhibits TWIST1 promoter activity and decreases its expression in breast cancer cell lines; leading to the inhibition of epithelial-mesenchymal transition (EMT)
EMT↓,
mTOR↓, thymoquinone also attenuated mTOR activity, and inhibited PI3K/Akt signaling in bladder cancer
PI3K↓,
Akt↓,
BioAv↓, Thymoquinone is chemically hydrophobic, which causes its poor solubility, and thus bioavailability. bioavailability of thymoquinone was reported ~58% with a lag time of ~23 min
ChemoSen↑, Some studies revealed that thymoquinone in combination with other chemotherapeutic drugs can show better anticancer activities
BioAv↑, Thymoquinone-loaded liposomes (TQ-LP) and thymoquinone loaded in liposomes modified with Triton X-100 (XLP) with diameters of about 100 nm were found to maintain stability, improve bioavailability and maintain thymoquinone’s anticancer activity
PTEN↑, Thymoquinone also induces apoptosis by up-regulating PTEN
chemoPv↑, A recent study showed that thymoquinone can potentiate the chemopreventive effect of vitamin D during the initiation phase of colon cancer in rat model
RadioS↑, thymoquinone also mediates radiosensitization and cancer chemo-radiotherapy
*Half-Life↝, Thymoquinone-loaded nanostructured lipid carrier (TQ-NLC) has been developed to improve its bioavailability (elimination half-life ~5 hours)
*BioAv↝, calculated absolute bioavailability of thymoquinone was reported ~58% with a lag time of ~23 min by Alkharfy et al.

3425- TQ,    Advances in research on the relationship between thymoquinone and pancreatic cancer
Apoptosis↑, TQ can inhibit cell proliferation, promote cancer cell apoptosis, inhibit cell invasion and metastasis, enhance chemotherapeutic sensitivity, inhibit angiogenesis, and exert anti-inflammatory effects.
TumCP↓,
TumCI↓,
TumMeta↓,
ChemoSen↑,
angioG↓,
Inflam↓,
NF-kB↓, These anticancer effects predominantly involve the nuclear factor (NF)-κB, phosphoinositide 3 kinase (PI3K)/Akt, Notch, transforming growth factor (TGF)-β, c-Jun N-terminal kinase (JNK)
PI3K↓,
Akt↓,
TGF-β↓,
Jun↓,
p38↑, and p38 mitogen-activated protein kinase (MAPK) signaling pathways as well as the regulation of the cell cycle, matrix metallopeptidase (MMP)-9 expression, and pyruvate kinase isozyme type M2 (PKM2) activity.
MAPK↑, activation of the JNK and p38 MAPK
MMP9↓,
PKM2↓, decrease in PKM2 activity
ROS↑, ROS-mediated activation
JNK↑, activation of the JNK and p38 MAPK
MUC4↓, downregulation of MUC4;
TGF-β↑, TQ led to the activation of the TGF-β pathway and subsequent downregulation of MUC4
Dose↝, Q acts as an antioxidant (free radical scavenger) at low concentrations and as a pro-oxidant at high concentrations.
FAK↓, TQ can inhibit several key molecules such as FAK, Akt, NF-κB, and MMP-9 and that these molecules interact in a cascade to affect the metastasis of pancreatic cancer
NOTCH↓, TQ involved in increasing chemosensitivity consist of blocking the Notch1/PTEN, PI3K/Akt/mTOR, and NF-κB signaling pathways, reducing PKM2 expression, and inhibiting the Warburg effect.
PTEN↑, it also restored the PTEN protein that had been inhibited by GEM
mTOR↓,
Warburg↓, reducing PKM2 expression, and inhibiting the Warburg effect.
XIAP↓,
COX2↓,
Casp9↑,
Ki-67↓,
CD34↓,
VEGF↓,
MCP1↓,
survivin↓,
Cyt‑c↑,
Casp3↑,
H4↑,
HDAC↓,

3427- TQ,    Chemopreventive and Anticancer Effects of Thymoquinone: Cellular and Molecular Targets
ROS⇅, It appears that the cellular and/or physiological context(s) determines whether TQ acts as a pro-oxidant or an anti-ox- idant in vivo
Fas↑, Figure 2, cell death
DR5↑,
TRAIL↑,
Casp3↑,
Casp8↑,
Casp9↑,
P53↑,
mTOR↓,
Bcl-2↓,
BID↓,
CXCR4↓,
JNK↑,
p38↑,
MAPK↑,
LC3II↑,
ATG7↑,
Beclin-1↑,
AMPK↑,
PPARγ↑, cell survival
eIF2α↓,
P70S6K↓,
VEGF↓,
ERK↓,
NF-kB↓,
XIAP↓,
survivin↓,
p65↓,
DLC1↑, epigenetic
FOXO↑,
TET2↑,
CYP1B1↑,
UHRF1↓,
DNMT1↓,
HDAC1↓,
IL2↑, inflammation
IL1↓,
IL6↓,
IL10↓,
IL12↓,
TNF-α↓,
iNOS↓,
COX2↓,
5LO↓,
AP-1↓,
PI3K↓, invastion
Akt↓,
cMET↓,
VEGFR2↓,
CXCL1↓,
ITGA5↓,
Wnt↓,
β-catenin/ZEB1↓,
GSK‐3β↓,
Myc↓,
cycD1/CCND1↓,
N-cadherin↓,
Snail↓,
Slug↓,
Vim↓,
Twist↓,
Zeb1↓,
MMP2↓,
MMP7↓,
MMP9↓,
JAK2↓, cell proliferiation
STAT3↓,
NOTCH↓,
cycA1/CCNA1↓,
CDK2↓,
CDK4↓,
CDK6↓,
CDC2↓,
CDC25↓,
Mcl-1↓,
E2Fs↓,
p16↑,
p27↑,
P21↑,
ChemoSen↑, Such chemo-potentiating effects of TQ in different cancer cells have been observed with 5-fluorouracil in gastric cancer and colorectal cancer models


Showing Research Papers: 1 to 31 of 31

* indicates research on normal cells as opposed to diseased cells
Total Research Paper Matches: 31

Pathway results for Effect on Cancer / Diseased Cells:


Redox & Oxidative Stress

antiOx↓, 1,   antiOx↑, 1,   ATF3↑, 1,   Catalase↓, 1,   Ferroptosis↑, 1,   GSH↑, 1,   GSR↑, 1,   GSTA1↑, 1,   GSTs↑, 1,   HO-1↓, 2,   HO-1↑, 1,   HO-2↓, 1,   lipid-P↑, 1,   MAD↓, 1,   MDA↓, 1,   NQO1↑, 1,   NRF2↓, 1,   NRF2↑, 3,   p‑NRF2↓, 1,   ROS↓, 3,   ROS↑, 19,   ROS⇅, 2,   i-ROS↑, 1,   SIRT3↑, 1,   SOD↓, 1,   SOD↑, 1,   Trx1↑, 1,   TrxR↓, 1,  

Mitochondria & Bioenergetics

AIF↑, 2,   ATP↓, 3,   CDC2↓, 3,   CDC25↓, 1,   EGF↓, 1,   ETC↑, 1,   FGFR1↓, 1,   MEK↓, 2,   mitResp↓, 2,   MMP↓, 12,   OCR↓, 1,   Raf↓, 2,   XIAP↓, 6,  

Core Metabolism/Glycolysis

ALAT↓, 2,   AMPK↑, 4,   p‑AMPK↑, 1,   ATG7↑, 1,   cMyc↓, 5,   ECAR↝, 1,   GlucoseCon↓, 1,   Glycolysis↓, 4,   HK2↓, 1,   lactateProd↓, 1,   LDH↓, 1,   LDH↑, 1,   LDHA↓, 2,   NADH:NAD↓, 1,   NADPH↑, 1,   PDH↝, 1,   PDK1?, 2,   PDK1↓, 1,   PIK3CA↓, 1,   PKM2↓, 1,   PPARγ↓, 1,   PPARγ↑, 1,   p‑S6K↓, 1,   SIRT1↓, 3,   SREBP1↓, 1,   TCA↑, 1,   Warburg↓, 2,  

Cell Death

Akt↓, 15,   Akt↑, 1,   p‑Akt↓, 3,   APAF1↑, 1,   Apoptosis↓, 1,   Apoptosis↑, 11,   ASK1↑, 1,   BAD↑, 1,   Bak↑, 1,   BAX↑, 8,   Bax:Bcl2↑, 3,   Bcl-2↓, 9,   Bcl-xL↓, 3,   Bcl-xL↑, 1,   BID↓, 1,   Casp↑, 2,   Casp3↓, 1,   Casp3↑, 12,   cl‑Casp3↑, 1,   Casp8↑, 4,   Casp9↑, 10,   cl‑Casp9↑, 1,   proCasp9↓, 1,   Chk2↓, 1,   Cyt‑c↑, 10,   Diablo↑, 1,   DR4↑, 1,   DR5↑, 5,   Fas↑, 1,   FasL↑, 2,   Ferroptosis↑, 1,   HEY1↓, 1,   hTERT/TERT↓, 2,   IAP1↓, 1,   IAP2↑, 1,   iNOS↓, 2,   JNK↑, 4,   MAPK↓, 3,   MAPK↑, 5,   Mcl-1↓, 4,   MDM2↓, 2,   Myc↓, 3,   NOXA↑, 1,   p27↑, 5,   p38↑, 4,   PUMA↑, 1,   survivin↓, 5,   Telomerase↓, 3,   TRAIL↑, 1,   TRAIL⇅, 1,   TRAILR↑, 1,   TumCD↑, 1,  

Kinase & Signal Transduction

HER2/EBBR2↓, 1,  

Transcription & Epigenetics

cJun↓, 1,   H3↑, 1,   H4↑, 1,   HATs↑, 1,   miR-21↑, 1,   p‑pRB↓, 1,   tumCV↓, 2,  

Protein Folding & ER Stress

CHOP↑, 3,   eIF2α↓, 1,   ER Stress↑, 2,   GRP78/BiP↓, 1,   GRP78/BiP↑, 1,   HSP70/HSPA5↓, 1,   HSP70/HSPA5↑, 1,   HSP90↓, 1,  

Autophagy & Lysosomes

Beclin-1↑, 3,   BNIP3↑, 1,   LC3B-II↑, 1,   LC3II↑, 2,   TumAuto↑, 2,  

DNA Damage & Repair

CHK1↓, 1,   CYP1B1↑, 1,   DNAdam↓, 1,   DNAdam↑, 3,   DNMT1↓, 3,   DNMT3A↓, 1,   DNMTs↓, 1,   p16↑, 1,   P53↑, 8,   PARP↓, 1,   PARP↑, 1,   cl‑PARP↑, 4,   PCNA↓, 2,   SIRT6↑, 1,   UHRF1↓, 1,   γH2AX↑, 1,  

Cell Cycle & Senescence

CDK1↓, 2,   CDK1↑, 1,   CDK2↓, 6,   CDK2↑, 2,   CDK4↓, 7,   cycA1/CCNA1↓, 2,   cycA1/CCNA1↑, 1,   CycB/CCNB1↓, 3,   cycD1/CCND1↓, 8,   cycD1/CCND1↑, 1,   cycE/CCNE↓, 3,   E2Fs↓, 3,   P21↑, 8,   p‑RB1↓, 2,   TumCCA?, 1,   TumCCA↓, 1,   TumCCA↑, 13,  

Proliferation, Differentiation & Cell State

ALDH↓, 2,   ALDH1A1↓, 2,   CD133↓, 4,   CD34↓, 1,   CD44↓, 4,   CDK8↓, 2,   cFos↓, 1,   CIP2A↓, 1,   cMET↓, 1,   CSCs↓, 12,   Diff↓, 1,   Diff↑, 1,   EMT↓, 13,   ERK↓, 6,   ERK↑, 1,   p‑ERK↓, 2,   FGF↓, 1,   FOXO↑, 1,   FOXO3↑, 1,   Gli1↓, 4,   GSK‐3β↓, 1,   GSK‐3β↝, 1,   p‑GSK‐3β↓, 1,   HDAC↓, 4,   HDAC1↓, 1,   HH↓, 4,   HMTs↓, 1,   IGFBP3↑, 2,   IGFR↓, 1,   Jun↓, 1,   Let-7↑, 1,   LRP6↓, 1,   miR-34a↑, 1,   mTOR↓, 12,   p‑mTOR↓, 1,   mTORC1↓, 1,   p‑mTORC1↓, 1,   n-MYC↓, 1,   Nanog↓, 1,   Nestin↓, 1,   NOTCH↓, 31,   OCT4↓, 3,   P70S6K↓, 1,   P90RSK↓, 1,   PI3K↓, 14,   PTEN↑, 5,   RAS↓, 2,   Shh↓, 5,   Smo↓, 4,   SOX2↓, 2,   STAT↓, 2,   STAT3↓, 12,   p‑STAT3↓, 2,   TOP2↓, 1,   TRPM7↓, 2,   TumCG↓, 5,   Wnt↓, 11,   Wnt/(β-catenin)↓, 3,  

Migration

5LO↓, 1,   AP-1↓, 2,   CA↓, 1,   Ca+2↑, 2,   Ca+2↝, 1,   CD31↓, 1,   DLC1↑, 1,   E-cadherin↑, 6,   ER-α36↓, 1,   FAK↓, 5,   p‑FAK↓, 1,   GLI2↓, 1,   ITGA5↓, 1,   Ki-67↓, 3,   KRAS↓, 1,   miR-203↑, 1,   MMP2↓, 13,   MMP7↓, 1,   MMP9↓, 12,   MMPs↓, 2,   MUC4↓, 2,   N-cadherin↓, 5,   PDGF↓, 2,   PKCδ↓, 2,   Rac1↓, 1,   Slug↓, 2,   SMAD3↓, 1,   Snail↓, 8,   SOX4↓, 1,   TGF-β↓, 5,   TGF-β↑, 2,   TIMP1↓, 1,   TIMP2↓, 1,   TSP-1↑, 1,   TumCI↓, 4,   TumCMig↓, 3,   TumCP↓, 7,   TumMeta↓, 3,   Twist↓, 5,   uPA↓, 5,   uPAR↓, 1,   Vim↓, 7,   Zeb1↓, 2,   ZO-1↑, 1,   α-tubulin↓, 1,   β-catenin/ZEB1↓, 11,  

Angiogenesis & Vasculature

angioG↓, 6,   ATF4↑, 1,   ECM/TCF↓, 1,   EGFR↓, 7,   p‑EGFR↓, 1,   Endoglin↑, 1,   HIF-1↓, 1,   Hif1a↓, 7,   PDGFR-BB↓, 1,   VEGF↓, 15,   VEGFR2↓, 5,  

Barriers & Transport

GLUT1↓, 1,   NHE1↓, 2,  

Immune & Inflammatory Signaling

CCR7↓, 1,   COX1↓, 2,   COX2↓, 11,   CRP↓, 1,   CXCL1↓, 1,   CXCR4↓, 2,   IL1↓, 3,   IL10↓, 2,   IL12↓, 1,   IL1β↓, 2,   IL2↑, 1,   IL6↓, 8,   Inflam↓, 4,   IκB↓, 1,   JAK↓, 4,   JAK1↓, 1,   JAK2↓, 2,   MCP1↓, 2,   NF-kB↓, 20,   p65↓, 1,   p‑p65↓, 1,   PD-1↓, 2,   PD-L1↓, 3,   PGE2↓, 3,   PSA↓, 1,   TLR4↓, 1,   TNF-α↓, 5,  

Cellular Microenvironment

pH↓, 1,  

Synaptic & Neurotransmission

ADAM10↓, 1,  

Protein Aggregation

PP2A↑, 1,  

Hormonal & Nuclear Receptors

AR↓, 2,   CDK6↓, 4,  

Drug Metabolism & Resistance

BioAv↓, 8,   BioAv↑, 5,   BioAv↝, 3,   ChemoSen↑, 15,   Dose?, 1,   Dose↓, 1,   Dose↑, 2,   Dose↝, 5,   Dose∅, 1,   eff↑, 12,   eff↝, 3,   Half-Life↓, 3,   Half-Life↝, 1,   P450↓, 1,   RadioS↑, 10,   selectivity↑, 4,   TET2↑, 1,  

Clinical Biomarkers

AFP↓, 1,   ALAT↓, 2,   ALP↓, 1,   AR↓, 2,   AST↓, 1,   CRP↓, 1,   E6↓, 1,   E7↓, 1,   EGFR↓, 7,   p‑EGFR↓, 1,   GutMicro↑, 1,   HER2/EBBR2↓, 1,   hTERT/TERT↓, 2,   IL6↓, 8,   Ki-67↓, 3,   KRAS↓, 1,   LDH↓, 1,   LDH↑, 1,   Myc↓, 3,   PD-L1↓, 3,   PSA↓, 1,  

Functional Outcomes

AntiCan↑, 3,   AntiTum↑, 1,   cardioP↑, 2,   chemoP↑, 2,   chemoPv↑, 1,   ChemoSideEff↓, 1,   hepatoP↑, 2,   OS↑, 1,   RenoP↑, 1,   toxicity↓, 2,   toxicity↝, 1,   toxicity∅, 1,  
Total Targets: 373

Pathway results for Effect on Normal Cells:


Redox & Oxidative Stress

antiOx↑, 6,   Catalase↑, 2,   GPx↑, 1,   GSH↑, 1,   GSR↑, 1,   GSTs↑, 1,   lipid-P↓, 1,   MDA↓, 1,   NRF2↓, 1,   NRF2↑, 1,   Prx↑, 1,   ROS↓, 5,   SOD↑, 2,   SOD2↑, 1,  

Mitochondria & Bioenergetics

MMP↑, 1,  

Core Metabolism/Glycolysis

LDH↓, 2,   SIRT1↑, 1,  

Cell Death

Casp3?, 1,   necrosis↓, 1,  

Proliferation, Differentiation & Cell State

HDAC↓, 1,   HDAC3↓, 1,   NOTCH↓, 1,   TRPM7↓, 1,   Wnt↓, 1,  

Migration

AntiAg↑, 1,   Ki-67↓, 1,   TIMP1↓, 1,  

Angiogenesis & Vasculature

NO↓, 1,  

Barriers & Transport

BBB↑, 1,  

Immune & Inflammatory Signaling

COX2↓, 1,   IL8↓, 1,   Imm↑, 1,   Inflam↓, 6,   NF-kB↓, 1,  

Synaptic & Neurotransmission

AChE↓, 1,  

Protein Aggregation

Aβ↓, 1,  

Drug Metabolism & Resistance

BioAv↓, 2,   BioAv↝, 1,   Half-Life↝, 1,  

Clinical Biomarkers

AST↓, 1,   Ki-67↓, 1,   LDH↓, 2,  

Functional Outcomes

AntiCan↑, 1,   AntiDiabetic↑, 2,   cardioP↑, 4,   chemoPv↑, 2,   hepatoP↑, 3,   motorD↑, 1,   neuroP↑, 5,   Obesity↓, 1,   Pain↓, 1,   toxicity↓, 1,   toxicity∅, 1,  

Infection & Microbiome

Bacteria↓, 2,  
Total Targets: 54

Scientific Paper Hit Count for: NOTCH,
3 Carvacrol
3 Curcumin
3 Ellagic acid
3 Niclosamide (Niclocide)
3 Resveratrol
3 Thymoquinone
2 Quercetin
2 Sulforaphane (mainly Broccoli)
1 Ashwagandha(Withaferin A)
1 Baicalein
1 Berberine
1 Boswellia (frankincense)
1 Cisplatin
1 Thymol-Thymus vulgaris
1 Sorafenib (brand name Nexavar)
1 Chlorogenic acid
1 EGCG (Epigallocatechin Gallate)
1 HydroxyTyrosol
1 Luteolin
1 Naringin
1 Psoralidin
1 Pterostilbene
1 Silymarin (Milk Thistle) silibinin
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#:%  Target#:220  State#:%  Dir#:1
  wNotes=on  sortOrder:rid,rpid

 

Home Page