N-cadherin Cancer Research Results

N-cadherin, N-cadherin: Click to Expand ⟱
Source:
Type:
Also known as Cadherin2 (CDH2).
N-cadherin is a type of cell adhesion molecule that plays a crucial role in the development and maintenance of tissue structure. In the context of cancer, N-cadherin has been implicated in the progression and metastasis of various types of tumors.
N-cadherin expression is increased in various types of cancer.
Normally, N-cadherin is expressed in mesenchymal cells, such as fibroblasts and smooth muscle cells. However, in cancer cells, N-cadherin expression is often upregulated, which can contribute to the epithelial-to-mesenchymal transition (EMT). EMT is a process by which epithelial cells acquire a more mesenchymal phenotype, which is characterized by increased motility, invasiveness, and resistance to apoptosis.
The expression of N-cadherin in cancer cells is closely associated with tumorigenesis and metastasis. Additionally, the soluble N-cadherin level in the serum of cancer patients is much higher than that in the serum of healthy patients, revealing a positive relation with poor prognosis.
Scientific Papers found: Click to Expand⟱
5433- AG,    Mechanisms of astragalus polysaccharide enhancing STM2457 therapeutic efficacy in m6A-mediated OSCC treatment
- vitro+vivo, OS, NA
other↓, Combined STM2457 and APS treatment significantly reduced m6A levels, METTL3, HNRNPA2B1, and FOXQ1 expression, and mRNA stability compared to single-drug treatments, approaching or surpassing METTL3 silencing effects.
TumCP↓, The combination markedly suppressed cell proliferation, migration, invasion, and EMT, with increased E-cadherin and decreased N-cadherin levels.
TumCMig↓,
TumCI↓,
EMT↓,
E-cadherin↑,
N-cadherin↓,
TumCG↓, In vivo, combination therapy significantly reduced tumor growth and FOXQ1 expression, outperforming single-drug treatments.

5438- AG,    Mechanisms of astragalus polysaccharide enhancing STM2457 therapeutic efficacy in mA-mediated OSCC treatment
- vitro+vivo, NA, NA
TumCP↓, combination markedly suppressed cell proliferation, migration, invasion, and EMT, with increased E-cadherin and decreased N-cadherin levels.
TumCMig↓,
TumCI↓,
EMT↓,
E-cadherin↑,
N-cadherin↓,

257- AL,  Cisplatin,    Allicin Overcomes Hypoxia Mediated Cisplatin Resistance in Lung Cancer Cells through ROS Mediated Cell Death Pathway and by Suppressing Hypoxia Inducible Factors
- in-vitro, NSCLC, A549
ROS↑, apoptosis and autophagy pathway in A549 cells by ROS accumulation and facilitating S/G2-M phase arrest in both normoxia as well as hypoxia
HIF-1↓,
E-cadherin↑,
N-cadherin↓,
antiOx↓, ROS trigger cell death when its generation reached toxic threshold level by overcoming the antioxidant capacity of the cell and inducing irreversible oxidative modifications of lipid, protein or DNA [30, 48]
Dose↝, 10μg/ml (LD) and 40μg/ml (HD) allicin for 24hr

244- Api,    Inhibition of the STAT3 signaling pathway contributes to apigenin-mediated anti-metastatic effect in melanoma
- in-vivo, Melanoma, B16-F10 - in-vivo, Melanoma, A375 - in-vivo, Melanoma, G361
STAT3↓,
MMP2↓,
MMP9↓,
VEGF↓,
Twist↓, Twist1
E-cadherin↑,
N-cadherin↓,
EMT↓,

5380- ART/DHA,    Artemisinin and Its Derivatives as Potential Anticancer Agents
- Review, Var, NA
TumCG↓, Artemisinin (1, Figure 2) could suppress cell growth [16], reduce angiogenesis-related factors [17], and induce ferroptosis [18] in breast cancer cell lines
angioG↓,
Ferroptosis↑,
TumCP↑, Dihydroartemisinin (2, Figure 2) exhibited anticancer effects against breast cancer by suppressing cell proliferation [16], inhibiting angiogenesis [19], inducing autophagy [20] and pyroptosis [21], and targeting cancer stem cells (CSCs) [
TumAuto↑,
CSCs↑,
eff↑, Dihydroartemisinin is more potent than artemisinin, as the IC50 values at 24 h were lower on MCF-7 (129.1 μM versus 396.6 μM) and MDA-MB-231 (62.95 μM versus 336.63 μM)
YAP/TEAD↓, Additionally, dihydroartemisinin was proven to have the ability to reduce the expression of yes-associated protein 1 (YAP1), which has been commonly used as a prognostic marker in liver cancer.
TumCCA↑, induced G0/G1 cell cycle arrest and apoptosis by promoting oxygen species (ROS) accumulation.
ROS↑,
ChemoSen↑, The application of combination treatment using artemisinin and its derivatives with commonly used chemotherapy drugs, such as cisplatin, carboplatin, doxorubicin, temozolomide, etc., always exhibits significantly improved anticancer effects
N-cadherin↓, and inhibiting the proliferation, colony formation, and invasiveness of colon cancer cells by inhibiting NRP2, N-cadherin, and Vimentin expression
Vim↓,
MMP9↓, by decreasing the expression of HuR and matrix metalloproteinase (MMP)-9 proteins [24],
eff↑, Further investigations suggested that both dihydroartemisinin treatment and the loss of PRIM2 could lead to a decreased GSH level and induce cellular lipid ROS and mitochondrial MDA expression.
STAT3↓, Recently, artemisinin and its derivatives were reported to have potential as direct STAT3 inhibitors [98].
CD133↓, dihydroartemisinin treatment could significantly reduce the expression of CSC markers (CD133, CD44, Nanog, c-Myc, and OCT4) by downregulating Akt/mTOR pathway
CD44↓,
Nanog↓,
cMyc↓,
OCT4↓,
Akt↓,
mTOR↓,

570- ART/DHA,    Artemisinin and its derivatives can significantly inhibit lung tumorigenesis and tumor metastasis through Wnt/β-catenin signaling
- vitro+vivo, NSCLC, A549 - vitro+vivo, NSCLC, H1299
TumCCA↑, arresting cell cycle in G1 phase.
CSCs↓,
TumCI↓,
TumCMig↓,
TumCG↓,
Wnt/(β-catenin)↓, main pathway
Nanog↓,
SOX2↓,
OCT4↓, oct3/4
N-cadherin↓,
Vim↓,
E-cadherin↑,

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↓,

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↓,

3166- Ash,    Exploring the Multifaceted Therapeutic Potential of Withaferin A and Its Derivatives
- Review, Var, NA
*p‑PPARγ↓, preventing the phosphorylation of peroxisome proliferator-activated receptors (PPARγ)
*cardioP↑, cardioprotective activity by AMP-activated protein kinase (AMPK) activation and suppressing mitochondrial apoptosis.
*AMPK↑,
*BioAv↝, The oral bioavailability was found to be 32.4 ± 4.8% after 5 mg/kg intravenous and 10 mg/kg oral WA administration.
*Half-Life↝, The stability studies of WA in gastric fluid, liver microsomes, and intestinal microflora solution showed similar results in male rats and humans with a half-life of 5.6 min.
*Half-Life↝, WA reduced quickly, and 27.1% left within 1 h
*Dose↑, WA showed that formulation at dose 4800 mg having equivalent to 216 mg of WA, was tolerated well without showing any dose-limiting toxicity.
*chemoPv↑, Here, we discuss the chemo-preventive effects of WA on multiple organs.
IL6↓, attenuates IL-6 in inducible (MCF-7 and MDA-MB-231)
STAT3↓, WA displayed downregulation of STAT3 transcriptional activity
ROS↓, associated with reactive oxygen species (ROS) generation, resulted in apoptosis of cells. The WA treatment decreases the oxidative phosphorylation
OXPHOS↓,
PCNA↓, uppresses human breast cells’ proliferation by decreasing the proliferating cell nuclear antigen (PCNA) expression
LDH↓, WA treatment decreases the lactate dehydrogenase (LDH) expression, increases AMP protein kinase activation, and reduces adenosine triphosphate
AMPK↑,
TumCCA↑, (SKOV3 andCaOV3), WA arrest the G2/M phase cell cycle
NOTCH3↓, It downregulated the Notch-3/Akt/Bcl-2 signaling mediated cell survival, thereby causing caspase-3 stimulation, which induces apoptosis.
Akt↓,
Bcl-2↓,
Casp3↑,
Apoptosis↑,
eff↑, Withaferin-A, combined with doxorubicin, and cisplatin at suboptimal dose generates ROS and causes cell death
NF-kB↓, reduces the cytosolic and nuclear levels of NF-κB-related phospho-p65 cytokines in xenografted tumors
CSCs↓, WA can be used as a pharmaceutical agent that effectively kills cancer stem cells (CSCs).
HSP90↓, WA inhibit Hsp90 chaperone activity, disrupting Hsp90 client proteins, thus showing antiproliferative effects
PI3K↓, WA inhibited PI3K/AKT pathway.
FOXO3↑, Par-4 and FOXO3A proapoptotic proteins were increased in Pten-KO mice supplemented with WA.
β-catenin/ZEB1↓, decreased pAKT expression and the β-catenin and N-cadherin epithelial-to-mesenchymal transition markers in WA-treated tumors control
N-cadherin↓,
EMT↓,
FASN↓, WA intraperitoneal administration (0.1 mg) resulted in significant suppression of circulatory free fatty acid and fatty acid synthase expression, ATP citrate lyase,
ACLY↓,
ROS↑, WA generates ROS followed by the activation of Nrf2, HO-1, NQO1 pathways, and upregulating the expression of the c-Jun-N-terminal kinase (JNK)
NRF2↑,
HO-1↑,
NQO1↑,
JNK↑,
mTOR↓, suppressing the mTOR/STAT3 pathway
neuroP↑, neuroprotective ability of WA (50 mg/kg b.w)
*TNF-α↓, WA attenuate the levels of neuroinflammatory mediators (TNF-α, IL-1β, and IL-6)
*IL1β↓,
*IL6↓,
*IL8↓, WA decreases the pro-inflammatory cytokines (IL-6, TNFα, IL-8, IL-18)
*IL18↓,
RadioS↑, radiosensitizing combination effect of WA and hyperthermia (HT) or radiotherapy (RT)
eff↑, WA and cisplatin at suboptimal dose generates ROS and causes cell death [41]. The actions of this combination is attributed by eradicating cells, revealing markers of cancer stem cells like CD34, CD44, Oct4, CD24, and CD117

4816- ASTX,    Potent carotenoid astaxanthin expands the anti-cancer activity of cisplatin in human prostate cancer cells
- in-vitro, Pca, NA
*antiOx↑, ASX has protective effects on various diseases, such as Parkinson’s disease and cancer by showing potent antioxidant and anti-inflammatory properties.
*Inflam↓,
ChemoSen↑, Additionally, we determined that it exhibited synergistic action with cisplatin and significantly enhanced apoptotic cell death in PCa cells. (beware of dose required for this?)
E-cadherin↑, graphical abstract
N-cadherin↓,
VEGF↓,
cMyc↓,
PSA↓,
cl‑Casp3↑, ASTX improves the cisplatin induces caspase 3 cleavage and PARP1 activation
PARP1↑,

1098- BA,    Baicalein inhibits fibronectin-induced epithelial–mesenchymal transition by decreasing activation and upregulation of calpain-2
- in-vitro, Nor, MCF10 - in-vivo, NA, NA
*TumCMig↓,
*F-actin↓,
*E-cadherin↑,
*ZO-1↑,
*N-cadherin↓,
*Vim↓,
*Snail↓,
*cal2↓, baicalein inhibited calpain-2 by decreasing intracellular calcium ion levels
*Ca+2↝, Effects of baicalein on fibronectin (FN)-induced intracellular elevation of Ca2+ Returns elevated levels close to back to original levels.

5251- Ba,    The Fascinating Effects of Baicalein on Cancer: A Review
- Review, Var, NA
AntiTum↑, The anti-tumor functions of baicalein are mainly due to its capacities to inhibit complexes of cyclins to regulate the cell cycle, to scavenge oxidative radicals, to attenuate mitogen activated protein kinase (MAPK), protein kinase B (Akt) or mammali
TumCCA↓,
ROS↓,
MAPK↓,
Akt↓,
mTOR↓,
Casp3↑, , to induce apoptosis by activating caspase-9/-3 and to inhibit tumorinvasion and metastasis by reducing the expression of matrix metalloproteinase-2/-9 (MMP-2/-9).
Casp9↑,
TumCI↓,
TumMeta↓,
MMP2↓,
MMP9↓,
Securin↓, Baicalein also induced cell death by reducing the expression of securin, while also inhibiting cancer cell death by affecting the expression of p-AKT and γ-H2AX [26].
γH2AX↝,
N-cadherin↓, Baicalein also decreased the expression of metastasis-associated molecules, including N-cadherin, vimentin, ZEB1, and ZEB2.
Vim↓,
Zeb1↓,
ZEB2↓,
TumCMig↓, researchers demonstrated that baiclalein inhibited cellular adhesion, migration, invasion, and growth of HCC cells both in vitro and in vivo.
TumCG↑,
12LOX↓, Baicalein is an inhibitor of 12-LOX and induced apoptosis, morphological changes, and carbonic anhydrase expression in PaCa cells.
DR5↑, Baicalein lessened this resistance to TRAIL by upregulating DR5 expression and promoting the expression of ROS, thus causing TRAIL sensitization in PC3 cells [85]
ROS↑,
RadioS↑, baicalein increased the sensitivity of prostate cancer cells to radiation without affecting this sensitivity in normal cells
ChemoSen↑, Combination therapy of baicalein with paclitaxel, which were assembled by nanoparticles, was demonstrated to have synergistic anticancer effects in A549 lung cancer cells and in mice bearing A549/PTX drug-resistant lung cancer xenografts [97].
BioAv↓, It is worth noting that the bioavailability of baicalein in vivo remains low.

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

2296- Ba,    The most recent progress of baicalein in its anti-neoplastic effects and mechanisms
- Review, Var, NA
CDK1↓, graphical abstract
Cyc↓,
p27↑,
P21↑,
P53↑,
TumCCA↑, Cell cycle arrest
TumCI↓, Inhibit invastion
MMP2↓,
MMP9↓,
E-cadherin↑,
N-cadherin↓,
Vim↓,
LC3A↑,
p62↓,
p‑mTOR↓,
PD-L1↓,
CAFs/TAFs↓,
VEGF↓,
ROCK1↓,
Bcl-2↓,
Bcl-xL↓,
BAX↑,
ROS↑,
cl‑PARP↑,
Casp3↑,
Casp9↑,
PTEN↑, A549, H460
MMP↓, ↓mitochondrial transmembrane potential, redistribution of cytochrome c,
Cyt‑c↑,
Ca+2↑, ↑Ca2+
PERK↑, ↑PERK, ↑IRE1α, ↑CHOP,
IRE1↑,
CHOP↑,
Copper↑, ↑Cu+2
Snail↓, ↓Snail, ↓vimentin, ↓Twist1,
Vim↓,
Twist↓,
GSH↓, ↑ROS, ↓GSH, ↑MDA, ↓MMP, ↓NRF2, ↓HO-1, ↓GPX4, ↓FTH1, ↑TFR1, ↓p-JAK2, ↓p-STAT3
NRF2↓,
HO-1↓,
GPx4↓,
XIAP↓, ↓Bcl-2, ↓Bcl-xL, ↓XIAP, ↓surviving
survivin↓,
DR5↑, ↑ROS, ↑DR5

1398- BBR,    Berberine inhibits the progression of renal cell carcinoma cells by regulating reactive oxygen species generation and inducing DNA damage
- in-vitro, Kidney, NA
TumCP↓,
TumCMig↓,
ROS↑,
Apoptosis↑,
BAX↑,
BAD↑,
Bak↑,
Cyt‑c↑,
cl‑Casp3↑,
cl‑Casp9↑,
E-cadherin↑,
TIMP1↑,
γH2AX↑,
Bcl-2↓,
N-cadherin↓,
Vim↓,
Snail↓,
RAD51↓,
PCNA↓,

1102- BBR,    Berberine suppressed epithelial mesenchymal transition through cross-talk regulation of PI3K/AKT and RARα/RARβ in melanoma cells
- in-vitro, Melanoma, B16-BL6
TumCMig↓,
TumCI↓,
EMT↓,
p‑PI3K↓,
p‑Akt↓,
RARα↓,
RARβ↑,
RARγ↑,
E-cadherin↑,
N-cadherin↓,

1031- BCA,    Biochanin A Suppresses Tumor Progression and PD-L1 Expression via Inhibiting ZEB1 Expression in Colorectal Cancer
- vitro+vivo, CRC, HCT116 - vitro+vivo, CRC, SW-620
PD-L1↓,
TumCG↓,
Zeb1↓, ZEB1 is a main regulator of PD-L1 expression in CRC.
E-cadherin↑,
N-cadherin↓,
EMT↓, blocked the EMT process in CRC.

2738- BetA,    Betulinic Acid Suppresses Breast Cancer Metastasis by Targeting GRP78-Mediated Glycolysis and ER Stress Apoptotic Pathway
- in-vitro, BC, MDA-MB-231 - in-vitro, BC, BT549 - in-vivo, NA, NA
TumCI↓, BA inhibited invasion and migration of highly aggressive breast cancer cells.
TumCMig↓,
Glycolysis↓, Moreover, BA could suppress aerobic glycolysis of breast cancer cells presenting as a reduction of lactate production, quiescent energy phenotype transition, and downregulation of aerobic glycolysis-related proteins.
lactateProd↓, lactate production in both MDA-MB-231 and BT-549 cells was significantly reduced following BA administration
GRP78/BiP↑, (GRP78) was also identified as the molecular target of BA in inhibiting aerobic glycolysis. BA treatment led to GRP78 overexpression, and GRP78 knockdown abrogated the inhibitory effect of BA on glycolysis.
ER Stress↑, Further studies demonstrated that overexpressed GRP78 activated the endoplasmic reticulum (ER) stress sensor PERK.
PERK↑,
p‑eIF2α↑, Subsequent phosphorylation of eIF2α led to the inhibition of β-catenin expression, which resulted in the inhibition of c-Myc-mediated glycolysis.
β-catenin/ZEB1↓,
cMyc↓, These findings suggested that BA inhibited the β-catenin/c-Myc pathway by interrupting the binding between GRP78 and PERK and ultimately suppressed the glycolysis of breast cancer cells.
ROS↑, (i) the induction of cancer cell apoptosis via the mitochondrial pathway induced by the release of soluble factors or generation of reactive oxygen species (ROS)
angioG↓, (ii) the inhibition of angiogenesis [24];
Sp1/3/4↓, (iii) the degradation of transcription factor specificity protein 1 (Sp1)
DNAdam↑, (iv) the induction of DNA damage by suppressing topoisomerase I
TOP1↓,
TumMeta↓, BA Inhibits Metastasis of Highly Aggressive Breast Cancer Cells
MMP2↓, BA significantly decreased the expression of MMP-2 and MMP-9 secreted by breast cancer cells
MMP9↓,
N-cadherin↓, BA downregulated the levels of N-cadherin and vimentin as the mesenchymal markers, while increased E-cadherin which is an epithelial marker (Figure 2(c)), validating the EMT inhibition effects of BA in breast cancer cells.
Vim↓,
E-cadherin↑,
EMT↓,
LDHA↓, the levels of glycolytic enzymes, including LDHA and p-PDK1/PDK1, were all decreased in a dose-dependent manner by BA
p‑PDK1↓,
PDK1↓,
ECAR↓, extracellular acidification rate (ECAR), which reflects the glycolysis activity, was retarded following BA administration.
OCR↓, oxygen consumption rate (OCR), which is a marker of mitochondrial respiration, was also decreased simultaneously
Hif1a↓, BA could reduce prostate cancer angiogenesis via inhibiting the HIF-1α/stat3 pathway [39]
STAT3↓,

2741- BetA,    Betulinic acid triggers apoptosis and inhibits migration and invasion of gastric cancer cells by impairing EMT progress
- in-vitro, GC, SNU16 - in-vitro, GC, NCI-N87 - in-vivo, NA, NA
TumCG↓, BA had significant cytotoxic and inhibitory effects on GC cells in a dose- and time-dependent manner.
TumCMig↓, BA inhibited the migratory and invasive abilities of SNU-16 cells
TumCI↓,
N-cadherin↓, relative expression level of N-cadherin in SNU-16 cells was drastically down-regulated, and the expression of E-cadherin in SNU-16 cells was distinctly up-regulated in comparison to that in the control group, implying a break in the EMT process.
E-cadherin↑,
EMT↓,
Ki-67↓, proportions of Ki-67-positive and MMP2-positive cells were significantly lower in the tumour sections of the BA-treated group than those in the sections of the control group
MMP2↓,

2047- Buty,    Sodium butyrate inhibits migration and induces AMPK-mTOR pathway-dependent autophagy and ROS-mediated apoptosis via the miR-139-5p/Bmi-1 axis in human bladder cancer cells
- in-vitro, CRC, T24/HTB-9 - in-vitro, Nor, SV-HUC-1 - in-vitro, Bladder, 5637 - in-vivo, NA, NA
HDAC↓, Sodium butyrate (NaB) is a histone deacetylase inhibitor and exerts remarkable antitumor effects in various cancer cells
AntiTum↑,
TumCMig↓, NaB inhibited migration
AMPK↑, induced AMPK/mTOR pathway-activated autophagy and reactive oxygen species (ROS) overproduction via the miR-139-5p/Bmi-1 axis
mTOR↑,
TumAuto↑,
ROS↑, NaB initiates ROS overproduction
miR-139-5p↑, NaB upregulates miR-139-5p and depletes Bmi-1 in bladder cancer cells
BMI1↓,
TumCI?, NaB significantly inhibited cell migration dose-dependently
E-cadherin↑, E-cadherin was markedly increased, while the expression of N-cadherin, Vimentin, and Snail was decreased
N-cadherin↓,
Vim↓,
Snail↓,
cl‑PARP↑, increased expression levels of cleaved PARP, cleaved caspase-3, and Bax and the concurrent decrease in Bcl-2 and Bcl-xl
cl‑Casp3↑,
BAX↑,
Bcl-2↓,
Bcl-xL↓,
MMP↓, impairs mitochondrial membrane potential
PINK1↑, activates the PINK1/ PARKIN pathway
PARK2↑,
TumMeta↓, NaB inhibits tumor metastasis and growth in vivo
TumCG↓,
LC3II↑, a significant increase in the levels of cleaved caspase3, p-AMPK, and LC3B-II along with decreased Bmi-1 and Vimentin
p62↓, elevated LC3B-II levels and degradation of p62
eff↓, NAC abolished the impairment of MMP and ROS overproduction. Interestingly, NAC also significantly inhibited apoptosis induced by NaB

1517- CAP,    Capsaicin Inhibits Multiple Bladder Cancer Cell Phenotypes by Inhibiting Tumor-Associated NADH Oxidase (tNOX) and Sirtuin1 (SIRT1)
- in-vitro, Bladder, TSGH8301 - in-vitro, CRC, T24/HTB-9
ENOX2↓, capsaicin downregulates tNOX expression
TumCCA↑, Capsaicin Downregulates tNOX and Induces Cell Cycle Arrest at G1 Phase
ERK↓, inhibit the activation of ERK
p‑FAK↓,
p‑pax↓,
TumCMig↓,
EMT↓,
SIRT1↓, downregulation of sirtuin 1 (SIRT1) in these tNOX-knockdown cells
Dose∅, 100 and 200 μM effectively reduced tNOX expression in bladder cancer TSGH8301 and T24
ROS↑, capsaicin dose-dependently increased ROS generation
MMP↓,
Bcl-2↓,
Bak↑,
cl‑PARP↑,
Casp3↑,
SIRT1↓, 100 and 200 μM capsaicin decreased SIRT1 expression
ac‑P53↑, concurrently increased p53 acetylation
BIM↑, enhanced the expression level of Bim
p‑RB1↓, downregulation of phosphorylated Rb and cyclin D,
cycD1/CCND1↓,
Dose∅, Interestingly, cell migration was somewhat increased with 10 μM accompanied by up-regulation of tNOX expression
β-catenin/ZEB1↓,
N-cadherin↓,
E-cadherin↑,

5894- CAR,    Targeting Gastrointestinal Cancers with Carvacrol: Mechanistic Insights and Therapeutic Potential
- Review, Var, NA
AntiCan↑, Carvacrol has demonstrated strong anticancer properties by modulating multiple molecular pathways governing apoptosis, inflammation, angiogenesis, and metastasis.
Apoptosis↑,
Inflam↓,
angioG↓,
TumMeta↓,
selectivity↑, revealed its ability to selectively target cancer cells while sparing healthy tissue
BioAv↑, nanotechnology have further enhanced its pharmacological profile by improving solubility, stability, and tumor-targeted delivery.
ChemoSen↑, synergistic effects when used in combination with conventional chemotherapeutics.
Dose↝, 84.38% of OEO’s contents are ‘carvacrol’.
TumCP↓, limit metastasis, induce apoptosis, suppress tumor cell proliferation, and improve the effectiveness of traditional chemotherapy medications
hepatoP↑, Carvacrol shows biological activities, such as antimicrobial, antitumor, antimutagenic, antigenotoxic, anti-inflammatory, anti-angiogenic, hepatoprotective, and antihepatotoxic properties.
Casp3↑, induced apoptosis by activating caspase-3 and caspase-9 while downregulating Bcl-2 mRNA levels
Casp9↑,
Bcl-2↓,
ROS↑, carvacrol causes oxidative stress by increasing the production of reactive oxygen species (ROS) and depleting GSH levels, which results in strong lethal effects on AGS gastric cancer
GSH↓,
BAX↑, upregulating pro-apoptotic markers such as Bax, caspase-3, caspase-7, caspase-8, caspase-9, cytochrome C, Fas, Fas-associated death domain (FADD), and p53
Casp7↑,
Casp8↑,
Cyt‑c↑,
Fas↑,
FADD↑,
P53↑,
Bcl-2↓, downregulating anti-apoptotic Bcl-2.
TumMeta↓, preventing metastasis by limiting the migration and invasion of cancer cells by upregulating epithelial markers like E-Cadherin and tissue inhibitors of metalloproteinases 2 and 3 (TIMP2 and TIMP3)
TumCMig↓,
TumCI↓,
E-cadherin↑,
TIMP2↑,
TIMP3↑,
N-cadherin↓, downregulating mesenchymal markers like N-Cadherin and ZEB2
ZEB2↓,
*lipid-P↓, protects the liver from diethylnitrosamine (DEN)-induced hepatocellular carcinogenesis by reducing lipid peroxidation, restoring key liver enzymes (AST, ALT, ALP, LDH, cGT)
*AST↓,
*ALAT↓,
*ALP↓,
*LDH↓,
*SOD↑, and enhancing antioxidant defenses (SOD, CAT, GPx, GR, GSH)
*Catalase↑,
*GPx↑,
*GSR↑,
selectivity↑, while selectively inducing apoptosis in cancer cells without harming normal liver tissue
cl‑PARP↑, inhibits HepG2 cancer cell growth by activating caspase-3, promoting PARP cleavage, downregulating Bcl-2, and modulating the MAPK signaling pathway by selectively reducing ERK1/2 phosphorylation while activating p38
ERK↓,
p38↑,
OS↑, rats (aged 6–8 weeks) demonstrated that carvacrol enhances sorafenib efficacy in HCC, improving survival rates, reducing tumor progression, and mitigating sorafenib-induced cardiac and hepatic toxicity.
AFP↓, carvacrol reduces serum alpha-fetoprotein (AFP) and alpha-L-fucosidase (AFU) levels by downregulating COX-2 and oxidative stress, inhibits angiogenesis via VEGF suppression,
COX2↓,
VEGF↓,
PCNA↓, prevents tumor proliferation by downregulating proliferating cell nuclear antigen (PCNA) and Ki-67 through TNF-α suppression.
Ki-67↓,
TNF-α↓,
BioAv↓, Despite carvacrol’s promising effects in vitro and in vivo, limitations such as bioavailability and solubility challenge its therapeutic application.

1103- CBD,    Cannabidiol inhibits invasion and metastasis in colorectal cancer cells by reversing epithelial-mesenchymal transition through the Wnt/β-catenin signaling pathway
- vitro+vivo, NA, NA
Apoptosis↑,
TumCP↓,
TumCMig↓,
TumMeta↓,
EMT↓,
E-cadherin↑,
N-cadherin↓,
Snail↓,
Vim↓,
Hif1a↓,
Wnt/(β-catenin)↓,
AXIN1↑,
TumVol↓, orthotopic xenograft tumors
TumW↓,

6002- CGA,    Chlorogenic Acid: A Systematic Review on the Biological Functions, Mechanistic Actions, and Therapeutic Potentials
- Review, Var, NA - Review, Diabetic, NA - Review, AD, NA - Review, Park, NA - Review, Stroke, NA
*neuroP↑, including neuroprotection for neurodegenerative disorders and diabetic peripheral neuropathy, anti-inflammation, anti-oxidation, anti-pathogens, mitigation of cardiovascular disorders,
*Inflam↓,
*antiOx↑,
*cardioP↑, Cardiovascular Protective Effect
*NRF2↑, pivotal antioxidants by activating the Nrf2 pathway
*AMPK↑, It elevates AMPK pathways for the maintenance and restoration of metabolic homeostasis of glucose and lipids.
*SOD↑, figure1
*Catalase↑,
*GSH↑,
*GPx↑,
*ROS↓,
*TNF-α↓,
*IL6↓,
*NF-kB↓,
*COX2↓,
*glucose↓, CGA can attenuate glucose absorption
*TRPC1↓, CGA suppresses the levels of transient receptor potential canonical channel 1 (TRPC1) and decreases ROS and Ca2+, thus mitigating lysophosphatidylcholine (LPC)-induced endothelial injuries
*Ca+2↓,
*HO-1↑, enhancing superoxide dismutase (SOD), and producing NO and heme oxygenase (HO)-1
*NF-kB↓, CGAs can regulate NF-κB and PPARα pathways, lower HIF-1α expression, and suppress cardiac apoptotic signaling, thus executing beneficial effects against cardiac hypertrophy
*PPARα↝,
*Hif1a↓,
*JNK↓, CGA can inhibit NF-κB and JNK pathways, exhibiting cardioprotection
*BP↓, GCE (93 or 185 mg for 4 weeks) could lead to a reduction of 4.7 and 5.6 mmHg in levels of systolic blood pressure (SBP) and a decrease of 3.3 and 3.9 mmHg in levels of diastolic blood pressure (DBP)
*AntiDiabetic↑, CGA has shown its functions in protecting β cells from apoptosis, improving β cell function, facilitating glycemic control, and mitigating DM complications.
*hepatoP↑, CGA can mediate hepatoprotective roles in various pathological conditions of the liver via antioxidant and anti-inflammatory features
*TLR4↓, (1) It can inhibit TLR4-mediated activation of NF-κB, thus suppressing pro-inflammatory responses;
*NRF2↑, (3) it can increase the activity of the Nrf2 pathway
*Casp↓, (4) it can inhibit caspases’ activation to suppress hepatic apoptosis induced by chemicals or toxins.
*neuroP↑, CGA has shown diverse neuroprotective effects on various neuropathological conditions which may be exerted through inhibition of neuroinflammation, reduction in ROS production, prevention of oxidation, and suppression of neuronal apoptosis
*Aβ↓, CGA or extracts containing CGA can inhibit Aβ aggregation-caused cellular injury in SH-SY5Y cells, a neuroblastoma cell line
*LDH↓, CGA increases survival and decreases apoptosis via decreasing activities of lactate dehydrogenase (LDH) and the levels of MDA and raising the levels of SOD and GSH-Px
*MDA↓,
*memory↑, CGA prevents Aβ deposition and neuronal loss and ameliorates learning and memory deterioration in APP/PS2 mice
*AChE↓, CGA inhibits acetylcholinesterase (AChE) activity in rat brains, suggesting its beneficial effect against cognitive impairment
*eff↑, CGA protects against injury caused by cerebral ischemia/reperfusion
EMT↝, It also modulates the epithelial–mesenchymal transition (EMT) process of breast cancer cells by downregulation of N-cadherin and upregulation of E-cadherin
N-cadherin↓,
E-cadherin↑,
TumCCA↑, CGA can stall the cells in the S phase and cause DNA injury in human colon cancer cell lines such as HCT116 and HT29 by increasing ROS production, upregulation of phosphorylated p53, HO-1, and Nrf2
ROS↑,
p‑P53↑,
HO-1↑,
NRF2↑,
ChemoSen↑, CGA in combination with doxorubicin suppresses cellular metabolic activity, colony formation, and cell growth of U2OS and MG-63 cells by upregulating caspase-3 and PARP and suppressing the p44/42 MAPK pathway, thus inducing apoptosis
mtDam↑, mechanism involves CGA-mediated excessive ROS production, causing mitochondrial dysfunction, leading to increases in cleaved levels of caspase-3, caspase-9, PARP, and Bax/Bcl-2 ratio
Casp3↑,
Casp9↑,
PARP↑,
Bax:Bcl2↑,
TumCG↓, in vivo experiments showing that CGA can reduce tumor growth and volume in pancreatic cancer cell-bearing nude mice by modifying cancer cell metabolism through decreasing levels of cyclin D1, c-Myc, and cyclin-dependent kinase-2 (CDK-2),
cycD1/CCND1↓,
cMyc↓,
CDK2↓,
mitResp↓, interrupting mitochondrial respiration, and suppressing aerobic glycolysis
Glycolysis↓,
Hif1a↓, CGA arrests cells at the phase of G1 and inhibits cell viability of prostate cancer cell DU145 by suppressing the levels of HIF-1α and SPHK-1, PCNA, cyclin-D, CDK-4, p-Akt, p-GSK-3β, and VEGF
PCNA↓,
p‑GSK‐3β↓,
VEGF↓,
PI3K↓, inhibition of the PI3K/Akt/mTOR pathway
Akt↓,
mTOR↓,
OS↑, Extending Lifespan in Worms

1106- CGA,    Chlorogenic Acid Inhibits Epithelial-Mesenchymal Transition and Invasion of Breast Cancer by Down-Regulating LRP6
- vitro+vivo, BC, MCF-7
E-cadherin↑,
ZO-1↑,
Zeb1↓,
N-cadherin↓,
Vim↓,
Snail↓,
Slug↓,
MMP2↓,
MMP9↓,
TumCMig↓,
TumCI↓,
LRP6↓,
p‑LRP6↓,
β-catenin/ZEB1↓,
TumVol↓, in vivo
TumW↓,

2782- CHr,    Broad-Spectrum Preclinical Antitumor Activity of Chrysin: Current Trends and Future Perspectives
- Review, Var, NA - Review, Stroke, NA - Review, Park, NA
*antiOx↑, antioxidant, anti-inflammatory, hepatoprotective, neuroprotective
*Inflam↓, inhibitory effect of chrysin on inflammation and oxidative stress is also important in Parkinson’s disease
*hepatoP↑,
*neuroP↑,
*BioAv↓, Accumulating data demonstrates that poor absorption, rapid metabolism, and systemic elimination are responsible for poor bioavailability of chrysin in humans that, subsequently, restrict its therapeutic effects
*cardioP↑, cardioprotective [69], lipid-lowering effect [70]
*lipidLev↓,
*RenoP↑, Renoprotective
*TNF-α↓, chrysin reduces levels of pro-inflammatory cytokines, such as tumor necrosis factor-α (TNF-α) and interleukin-2 (IL-2).
*IL2↓,
*PI3K↓, induction of the PI3K/Akt signaling pathway by chrysin contributes to a reduction in oxidative stress and inflammation during cerebral I/R injury
*Akt↓,
*ROS↓,
*cognitive↑, Chrysin (25, 50, and 100 mg/kg) improves cognitive capacity, inflammation, and apoptosis to ameliorate traumatic brain injury
eff↑, chrysin and silibinin is beneficial in suppressing breast cancer malignancy via decreasing cancer proliferation
cycD1/CCND1↓, chrysin and silibinin induced cell cycle arrest via down-regulation of cyclin D1 and hTERT
hTERT/TERT↓,
VEGF↓, Administration of chrysin is associated with the disruption of hypoxia-induced VEGF gene expression
p‑STAT3↓, chrysin is capable of reducing STAT3 phosphorylation in hypoxic conditions without affecting the HIF-1α protein level.
TumMeta↓, chrysin is a potent agent in suppressing metastasis and proliferation of breast cancer cells during hypoxic conditions
TumCP↓,
eff↑, combination therapy of breast cancer cells using chrysin and metformin exerts a synergistic effect and is more efficient compared to chrysin alone
eff↑, combination of quercetin and chrysin reduced levels of pro-inflammatory factors, such as IL-1β, Il-6, TNF-α, and IL-10, via NF-κB down-regulation.
IL1β↓,
IL6↓,
NF-kB↓,
ROS↑, after chrysin administration, an increase occurs in levels of ROS that, subsequently, impairs the integrity of the mitochondrial membrane, leading to cytochrome C release and apoptosis induction
MMP↓,
Cyt‑c↑,
Apoptosis↑,
ER Stress↑, in addition to mitochondria, ER can also participate in apoptosis
Ca+2↑, Upon chrysin administration, an increase occurs in levels of ROS and cytoplasmic Ca2+ that mediate apoptosis induction in OC cells
TET1↑, In MKN45 cells, chrysin promotes the expression of TET1
Let-7↑, Chrysin is capable of promoting the expression of miR-9 and Let-7a as onco-suppressor factors in cancer to inhibit the proliferation of GC cells
Twist↓, Down-regulation of NF-κB, and subsequent decrease in Twist/EMT are mediated by chrysin administration, negatively affecting cervical cancer metastasis
EMT↓,
TumCCA↑, nduction of cell cycle arrest and apoptosis via up-regulation of caspase-3, caspase-9, and Bax are mediated by chrysin
Casp3↑,
Casp9↑,
BAX↑,
HK2↓, Chrysin administration (15, 30, and 60 mM) reduces the expression of HK-2 in hepatocellular carcinoma (HCC) cells to impair glucose uptake and lactate production.
GlucoseCon↓,
lactateProd↓,
Glycolysis↓, In addition to glycolysis metabolism impairment, the inhibitory effect of chrysin on HK-2 leads to apoptosis
SHP1↑, upstream modulator of STAT3 known as SHP-1 is up-regulated by chrysin
N-cadherin↓, Furthermore, N-cadherin and E-cadherin are respectively down-regulated and up-regulated upon chrysin administration in inhibiting melanoma invasion
E-cadherin↑,
UPR↑, chrysin substantially diminishes survival by ER stress induction via stimulating UPR, PERK, ATF4, and elF2α
PERK↑,
ATF4↑,
eIF2α↑,
RadioS↑, Irradiation combined with chrysin exerts a synergistic effect
NOTCH1↑, Irradiation combined with chrysin exerts a synergistic effect
NRF2↓, in reducing Nrf2 expression, chrysin down-regulates the expression of ERK and PI3K/Akt pathways—leading to an increase in the efficiency of doxorubicin in chemotherapy
BioAv↑, chrysin at the tumor site by polymeric nanoparticles leads to enhanced anti-tumor activity, due to enhanced cellular uptake
eff↑, Chrysin- and curcumin-loaded nanoparticles significantly promote the expression of TIMP-1 and TIMP-2 to exert a reduction in melanoma invasion

16- CP,  RES,    Resveratrol inhibits the hedgehog signaling pathway and epithelial-mesenchymal transition and suppresses gastric cancer invasion and metastasis
- in-vitro, GC, SGC-7901
HH↓, decrease in Gli-1, Snail and N-cadherin expression, and an increase in E-cadherin expression in the resveratrol and cyclopamine group compared
Gli1↓,
EMT↓, suggesting that resveratrol inhibited the Hh pathway and EMT, as did cyclopamine.
N-cadherin↓,
E-cadherin↑,
Snail↓,
TumCI↓, suppress invasion and metastasis in gastric cancer in vitro.
TumMeta↓, Resveratrol and cyclopamine inhibits the metastasis and invasion of SGC-7901 cells

11- CUR,    Curcumin inhibits hypoxia-induced epithelial‑mesenchymal transition in pancreatic cancer cells via suppression of the hedgehog signaling pathway
- in-vitro, PC, PANC1
HH↓, suppression of the hedgehog signaling pathway
Shh↓, Curcumin significantly decreased hypoxia-induced expression levels of SHH, SMO and GLI1.
Smo↓,
Gli1↓,
N-cadherin↓,
E-cadherin↑,
Vim↓,
TumCP↓, inhibit the hypoxia-induced cell proliferation, migration and invasion in pancreatic cancer,
TumCMig↓,
TumCI↓,
EMT↓, mediate the expression of EMT-related factors.
chemoPv↑, Curcumin might be a potential candidate for chemoprevention of this severe disease.

464- CUR,    Curcumin inhibits the viability, migration and invasion of papillary thyroid cancer cells by regulating the miR-301a-3p/STAT3 axis
- in-vitro, Thyroid, BCPAP - in-vitro, Thyroid, TPC-1
TumCI↓,
TumCI↓,
MMP2↓,
MMP9↓,
EMT↓,
STAT3↓,
miR-301a-3p↓,
STAT↓,
N-cadherin↓,
Vim↓,
Fibronectin↓,
p‑JAK↓,
p‑JAK2↓,
p‑JAK3↓,
p‑STAT1↓,
p‑STAT2↓,
E-cadherin↑,

413- CUR,    Curcumin attenuates lncRNA H19-induced epithelial-mesenchymal transition in tamoxifen-resistant breast cancer cells
- in-vitro, BC, MCF-7
N-cadherin↓,
E-cadherin↑,
H19↓, starts about 10% reduction with 5uM

478- CUR,    Curcumin decreases epithelial‑mesenchymal transition by a Pirin‑dependent mechanism in cervical cancer cells
- in-vitro, Cerv, SiHa
EMT↓,
N-cadherin↓,
Vim↓,
Slug↓,
Zeb1↓,
PIR↓,
Pirin↓,
E-cadherin↑,

433- CUR,    Curcumin Inhibits the Migration and Invasion of Non-Small-Cell Lung Cancer Cells Through Radiation-Induced Suppression of Epithelial-Mesenchymal Transition and Soluble E-Cadherin Expression
- in-vitro, Lung, A549
E-cadherin↓,
Vim↓,
Slug↓,
N-cadherin↓,
Snail↓, N-cadherin and Snail expression showed a slight decrease after treatment with different concentrations of curcumin.
MMP9↓, Curcumin inhibited MMP9 expression
EMT↓, Curcumin inhibits NSCLC migration and invasion by suppressing radiation-induced EMT and sE-cad expression by decreasing MMP9 expression

429- CUR,    TAp63α Is Involved in Tobacco Smoke-Induced Lung Cancer EMT and the Anti-cancer Activity of Curcumin via miR-19 Transcriptional Suppression
- in-vitro, Lung, H1299 - in-vitro, Lung, A549
TAp63α↑,
E-cadherin↑,
ZO-1↑,
Vim↓,
N-cadherin↓,
miR-19b↓, miR-19a, miR-19b

447- CUR,  OXA,    Curcumin reverses oxaliplatin resistance in human colorectal cancer via regulation of TGF-β/Smad2/3 signaling pathway
- vitro+vivo, CRC, HCT116
p‑p65↓,
Bcl-2↓,
Casp3↑,
EMT↓,
p‑SMAD2↓,
p‑SMAD3↓,
N-cadherin↓,
TGF-β↓,
E-cadherin↑,
TumVol↓,
TumCMig↓,

443- CUR,    Reduced Caudal Type Homeobox 2 (CDX2) Promoter Methylation Is Associated with Curcumin’s Suppressive Effects on Epithelial-Mesenchymal Transition in Colorectal Cancer Cells
- in-vitro, CRC, SW480
DNMT1↓,
DNMT3A↓,
N-cadherin↓,
Vim↓,
Wnt↓, Wnt3a
Snail↓, Snail1
Twist↓,
β-catenin/ZEB1↓,
E-cadherin↑,
EMT↓, Curcumin incubation inhibited EMT
CDX2↓,

1247- EMD,    Emodin exerts antitumor effects in ovarian cancer cell lines by preventing the development of cancer stem cells via epithelial mesenchymal transition
- vitro+vivo, Ovarian, SKOV3 - in-vitro, Ovarian, A2780S
TumCP↓,
TumCMig↓,
TumCI↓,
EMT↓,
N-cadherin↓,
Vim↓,
E-cadherin↑,
TumCG↓, vivo
CD133↓,
OCT4↓,
CSCs↓,

2857- FIS,    A review on the chemotherapeutic potential of fisetin: In vitro evidences
- Review, Var, NA
COX2↓, fisetin altered the expression of cyclooxygenase 2 (COX2) thereby suppressed the secretion of prostaglandin E2 ultimately resulting in the inhibition of epidermal growth factor receptor (EGFR) and NF-κB in human colon cancer cells HT29
PGE2↓,
EGFR↓,
Wnt↓, fisetin treatment inhibited the stimulation of Wnt signaling pathway via downregulating the expression of β-catenin and Tcell factor (TCF) 4
β-catenin/ZEB1↓,
TCF↑,
Apoptosis↑, fisetin triggers apoptosis in U266 cells through multiple pathways: enhancing the activation of caspase-3 and PARP cleavage, decreasing the expression of anti-apoptotic proteins (Bcl-2 and Mcl-1 L ),
Casp3↑,
cl‑PARP↑,
Bcl-2↓,
Mcl-1↓,
BAX↑, ncreasing the expression of pro-apoptotic proteins (Bax, Bim, and Bad)
BIM↑,
BAD↑,
Akt↓, decreasing the phosphorylation of AKT and mTOR and elevating the expression of acetyl CoA carboxylase (ACC
mTOR↓,
ACC↑,
Cyt‑c↑, release the cytochrome c and Smac/Diablo into the cytosol
Diablo↑,
cl‑Casp8↑, fisetin exhibited an increased level of cleaved caspase-8, Fas/Fas ligand, death receptor 5/TRAIL, and p53 levels in HCT-116 cells
Fas↑,
DR5↑,
TRAIL↑,
Securin↓, Securin gets degraded on exposure to fisetin in colon cancer cells.
CDC2↓, fisetin decreased the expression of cell division cycle proteins (CDC2 and CDC25C)
CDC25↓,
HSP70/HSPA5↓, Fisetin induced apoptosis as a result of the downregulation of HSP70 and BAG3 and the inhibition of Bcl-2, Bcl-x L and Mcl-1. T
CDK2↓, AGS 0, 25, 50, 75 μM – 24 and 48 h ↓CDK2, ↓CDK4, ↓cyclin D1, ↑casapse-3 cleavage
CDK4↓,
cycD1/CCND1↓,
MMP2↓, A549 0, 1, 5, 10 μM- 24 and 48 hr: ↓MMP-2, ↓u-PA, ↓NF- κB, ↓c-Fos, ↓c-Jun
uPA↓,
NF-kB↓,
cFos↓,
cJun↓,
MEK↓, ↓ MEK1/2 and ERK1/2 phosphorylation, ↓N-cadherin, ↓vimentin, ↓snail, ↓fibronectin, ↑E-cadherin, ↑desmoglein
p‑ERK↓,
N-cadherin↓,
Vim↓,
Snail↓,
Fibronectin↓,
E-cadherin↓,
NF-kB↑, increased expression of NF-κB p65 leading to apoptosis was due to ROS generation on exposure to fisetin
ROS↑,
DNAdam↑, increased ROS triggered cell death through PARP cleavage, DNA damage and mitochondrial membrane depolarization.
MMP↓,
CHOP↑, Though fisetin upregulated CHOP expression and increased the production of ROS, these events fail to induce apoptosis in Caki cells.
eff↑, 50 μM fisetin + 1 mM melatonin Sk-mel-28 Enhances anti-tumour activity [54] 20 μM fisetin + 1 mM melatonin MeWo Enhances anti-tumour activity [54] 10 μM fisetin + 0.1 μM melatonin A549 Induces autophagic cell death
ChemoSen↑, 20 μM fisetin + 5 μM sorafenib A375, SK-MEL-28 Suppresses invasion and metastasis [44] 40 μM fisetin + 10 μM cisplatin A549, A549-CR Enhances apoptosis

2845- FIS,    Fisetin: A bioactive phytochemical with potential for cancer prevention and pharmacotherapy
- Review, Var, NA
PI3K↓, block multiple signaling pathways such as the phosphatidylinositol-3-kinase/protein kinase B/mammalian target of rapamycin (PI3K/Akt/mTOR) and p38
Akt↓,
mTOR↓,
p38↓,
*antiOx↑, antioxidant, anti-inflammatory, antiangiogenic, hypolipidemic, neuroprotective, and antitumor effect
*neuroP↑,
Casp3↑, U266 cancer cell line through activation of caspase-3, downregulation of Bcl-2 and Mcl-1L, upregulation of Bax, Bim and Bad
Bcl-2↓,
Mcl-1↓,
BAX↑,
BIM↑,
BAD↑,
AMPK↑, activation of 5'adenosine monophosphate-activated protein kinase (AMPK), acetyl-CoA carboxylase (ACC) and decreased phosphorylation of AKT and mTOR were also observed
ACC↑,
DNAdam↑, DNA fragmentation, mitochondrial membrane depolarizatio
MMP↓,
eff↑, fisetin in combination with a citrus flavanone, hesperetin mediated apoptosis by mitochondrial membrane depolarization and caspase-3 act
ROS↑, NCI-H460 human non-small cell lung cancer line, fisetin generated reactive oxygen species (ROS), endoplasmic reticulum (ER) stress
cl‑PARP↑, fisetin treatment resulted in PARP cleavage
Cyt‑c↑, release of cyt. c
Diablo↑, release of cyt. c and Smac/DIABLO from mitochondria,
P53↑, increased p53 protein levels
p65↓, reduced phospho-p65 and Myc oncogene expression
Myc↓,
HSP70/HSPA5↓, fisetin causes inhibition of proliferation by the modulation of heat shock protein 70 (HSP70), HSP27
HSP27↓,
COX2↓, anti-proliferative effects of fisetin through the activation of apoptosis via inhibition of cyclooxygenase-2 (COX-2) and Wnt/EGFR/NF-κB signaling pathways
Wnt↓,
EGFR↓,
NF-kB↓,
TumCCA↑, The anti-proliferative effects of fisetin and hesperetin were shown to be occurred through S, G2/M, and G0/G1 phase arrest in K562 cell progression
CDK2↓, decrease in levels of cyclin D1, cyclin A, Cdk-4 and Cdk-2
CDK4↓,
cycD1/CCND1↓,
cycA1/CCNA1↓,
P21↑, increase in p21 CIP1/WAF1 levels in HT-29 human colon cancer cell
MMP2↓, fisetin has exhibited tumor inhibitory effects by blocking matrix metalloproteinase-2 (MMP- 2) and MMP-9 at mRNA and protein levels,
MMP9↓,
TumMeta↓, Antimetastasis
MMP1↓, fisetin also inhibited the MMP-14, MMP-1, MMP-3, MMP-7, and MMP-9
MMP3↓,
MMP7↓,
MET↓, promotion of mesenchymal to epithelial transition associated with a decrease in mesenchymal markers i.e. N-cadherin, vimentin, snail and fibronectin and an increase in epithelial markers i.e. E-cadherin
N-cadherin↓,
Vim↓,
Snail↓,
Fibronectin↓,
E-cadherin↑,
uPA↓, fisetin suppressed the expression and activity of urokinase plasminogen activator (uPA)
ChemoSen↑, combination treatment of fisetin and sorafenib reduced the migration and invasion of BRAF-mutated melanoma cells both in in-vitro
EMT↓, inhibited epithelial to mesenchymal transition (EMT) as observed by a decrease in N-cadherin, vimentin and fibronectin and an increase in E-cadherin
Twist↓, inhibited expression of Snail1, Twist1, Slug, ZEB1 and MMP-2 and MMP-9
Zeb1↓,
cFos↓, significant decrease in NF-κB, c-Fos, and c-Jun levels
cJun↓,
EGF↓, Fisetin inhibited epidermal growth factor (EGF)
angioG↓, Antiangiogenesis
VEGF↓, decreased expression of endothelial nitric oxide synthase (eNOS) and VEGF, EGFR, COX-2
eNOS↓,
*NRF2↑, significantly increased nuclear translocation of Nrf2 and antioxidant response element (ARE) luciferase activity, leading to upregulation of HO-1 expression
HO-1↑,
NRF2↓, Fisetin also triggered the suppression of Nrf2
GSTs↓, declined placental type glutathione S-transferase (GST-p) level in the liver of the fisetin- treated rats with hepatocellular carcinoma (HCC)
ATF4↓, Fisetin also rapidly increased the levels of both Nrf2 and ATF4

2825- FIS,    Exploring the molecular targets of dietary flavonoid fisetin in cancer
- Review, Var, NA
*Inflam↓, present in fruits and vegetables such as strawberries, apple, cucumber, persimmon, grape and onion, was shown to possess anti-microbial, anti-inflammatory, anti-oxidant
*antiOx↓, fisetin possesses stronger oxidant inhibitory activity than well-known potent antioxidants like morin and myricetin.
*ERK↑, inducing extracellular signal-regulated kinase1/2 (ERK)/c-myc phosphorylation, nuclear NF-E2-related factor-2 (Nrf2), glutamate cystine ligase and glutathione (GSH) levels
*p‑cMyc↑,
*NRF2↑,
*GSH↑,
*HO-1↑, activate Nrf2 mediated induction of hemeoxygenase-1 (HO-1) important for cell survival
mTOR↓, in our studies on fisetin in non-small lung cancer cells, we found that fisetin acts as a dual inhibitor PI3K/Akt and mTOR pathways
PI3K↓,
Akt↓,
TumCCA↑, fisetin treatment to LNCaP cells resulted in G1-phase arrest accompanied with decrease in cyclins D1, D2 and E and their activating partner CDKs 2, 4 and 6 with induction ofWAF1/p21 and KIP1/p27
cycD1/CCND1↓,
cycE/CCNE↓,
CDK2↓,
CDK4↓,
CDK6↓,
P21↑,
p27↑,
JNK↑, fisetin could inhibit the metastatic ability of PC-3 cells by suppressing of PI3 K/Akt and JNK signaling pathways with subsequent repression of matrix metalloproteinase-2 (MMP-2) and MMP-9
MMP2↓,
MMP9↓,
uPA↓, fisetin suppressed protein and mRNA levels of MMP-2 and urokinase-type plasminogen activator (uPA) in an ERK-dependent fashion.
NF-kB↓, decrease in the nuclear levels of NF-B, c-Fos, and c-Jun was noted in fisetin treated cells
cFos↓,
cJun↓,
E-cadherin↑, upregulation of E-cadherin and down-regulation of vimentin and N-cadherin.
Vim↓,
N-cadherin↓,
EMT↓, EMT inhibiting potential of fisetin has been reported in melanoma cells
MMP↓, The shift in mitochondrial membrane potential was accompanied by release of cytochrome c and Smac/DIABLO resulting in activation of the caspase cascade and cleavage of PARP
Cyt‑c↑,
Diablo↑,
Casp↑,
cl‑PARP↑,
P53↑, fisetin with induction of p53 protein
COX2↓, Fisetin down-regulated COX-2 and reduced the secretion of prostaglandin E2 without affecting COX-1 protein expression.
PGE2↓,
HSP70/HSPA5↓, It was shown that the induction of HSF1 target proteins, such as HSP70, HSP27 and BAG3 were inhibited in HCT-116 cells exposed to heat shock at 43 C for 1 h in the presence of fisetin
HSP27↓,
DNAdam↑, DNA fragmentation, an increase in the number of sub-G1 phase cells, mitochondrial membrane depolarization and activation of caspase-9 and caspase-3.
Casp3↑,
Casp9↑,
ROS↑, This was associated with production of intracellular ROS
AMPK↑, Fisetin induced AMPK signaling
NO↑, fisetin induced cytotoxicity and showed that fisetin induced apoptosis of leukemia cells through generation of NO and elevated Ca2+ activating the caspase
Ca+2↑,
mTORC1↓, Fisetin was shown to inhibit the mTORC1 pathway and its downstream components including p70S6 K, eIF4B and eEF2 K.
p70S6↓,
ROS↓, Others have also noted a similar decrease in ROS with fisetin treatment.
ER Stress↑, Induction of ER stress upon fisetin treatment, evident as early as 6 h, and associated with up-regulation of IRE1, XBP1s, ATF4 and GRP78, was followed by autophagy which was not sustained
IRE1↑,
ATF4↑,
GRP78/BiP↑,
eff↑, Combination of fisetin and the BRAF inhibitor sorafenib was found to be extremely effective in inhibiting the growth of BRAF-mutated human melanoma cells
eff↑, synergistic effect of fisetin and sorafenib was observed in human cervical cancer HeLa cells,
eff↑, Similarly, fisetin in combination with hesperetin induced apoptosis
RadioS↑, pretreatment with fisetin enhanced the radio-sensitivity of p53 mutant HT-29 cancer cells,
ChemoSen↑, potential of fisetin in enhancing cisplatin-induced cytotoxicity in various cancer models
Half-Life↝, intraperitoneal (ip) dose of 223 mg/kg body weight the maximum plasma concentration (2.53 ug/ml) of fisetin was reached at 15 min which started to decline with a first rapid alpha half-life of 0.09 h and a longer half-life of 3.12 h.

1113- FIS,    Fisetin suppresses migration, invasion and stem-cell-like phenotype of human non-small cell lung carcinoma cells via attenuation of epithelial to mesenchymal transition
- in-vitro, Lung, A549 - in-vitro, Lung, H1299
TumCI↓,
TumCMig↓,
EMT↓,
E-cadherin↑, A549
ZO-1↑, h1299
Vim↓,
N-cadherin↓,
MMP2↓,
CD44↓,
CD133↓,
β-catenin/ZEB1↓,
NF-kB↓,
EGFR↓,
STAT3↓,
CSCs↓, ability of fisetin to serve as a potential therapeutic agent on its capacity to attenuate the EMT program and inhibit migration, invasion and stem cell phenotype of lung cancer cells.

1116- GI,    6-Shogaol Inhibits the Cell Migration of Colon Cancer by Suppressing the EMT Process Through the IKKβ/NF-κB/Snail Pathway
- in-vitro, Colon, Caco-2 - in-vitro, CRC, HCT116
TumCG↓,
Apoptosis↑,
TumCMig↓,
MMP2↓, 80 µM
N-cadherin↓,
IKKα↓, IKKβ
p‑NF-kB↓,
Snail↓,
VEGF↓,

1118- GSE,    Grape Seed Proanthocyanidins Inhibit Migration and Invasion of Bladder Cancer Cells by Reversing EMT through Suppression of TGF- β Signaling Pathway
- in-vitro, Bladder, T24/HTB-9 - in-vitro, Bladder, 5637
TumCMig↓,
TumCI↓,
MMP2↓,
MMP9↓,
EMT↓,
N-cadherin↓,
Vim↓,
Slug↓,
E-cadherin↑,
ZO-1↑,
p‑SMAD2↓,
p‑SMAD3↓,
p‑Akt↓,
p‑ERK↓,
p‑p38↓,

1240- GSE,  PACs,    Grape Seed Proanthocyanidins Inhibit Melanoma Cell Invasiveness by Reduction of PGE2 Synthesis and Reversal of Epithelial-to-Mesenchymal Transition
- in-vitro, Melanoma, A375 - in-vitro, Melanoma, Hs294T
TumCMig↓,
TumCI↓,
COX2↓,
PGE2↓,
NF-kB↓, GSPs inhibited the activation of NF-κB/p65, an upstream regulator of COX-2
EMT↓, associated with reversal of epithelial-mesenchymal transition process
E-cadherin↑,
Vim↓,
Fibronectin↓,
N-cadherin↓,

2882- HNK,    Honokiol Suppresses Perineural Invasion of Pancreatic Cancer by Inhibiting SMAD2/3 Signaling
- in-vitro, PC, PANC1
TumCI↓, HNK can inhibit the invasion and migration of pancreatic cancer cells.
TumCMig↓,
p‑SMAD2↓, partially mediated by inhibition of SMAD2/3 phosphorylation.
p‑SMAD3↓,
EMT↓, HNK Inhibits Pancreatic Cancer Malignant Behaviors and EMT
N-cadherin↓, expression of N-cadherin and Vimentin was gradually downregulated, while HNK promoted the expression of E-cadherin in PANC-1
Vim↓,
E-cadherin↑,
Snail↓, HNK can inhibit breast cancer cell metastasis by blocking EMT through downregulating Snail/Slug protein translation
Slug↓,
Rho↓, Honokiol inhibits the migration of renal cell carcinoma through activation of the RhoA/ROCK/MLC signaling pathway
ROCK1↓,

2883- HNK,    Honokiol targets mitochondria to halt cancer progression and metastasis
- Review, Var, NA
ChemoSen↑, Combination of HNK with many traditional chemotherapeutic drugs as well as radiation sensitizes cancer cells to apoptotic death
BBB↓, HNK is also capable of crossing the BBB
Ca+2↑, HNK promotes human glioblastoma cancer cell apoptosis via regulation of Ca(2+) channels
Cyt‑c↑, release of mitochondrial cytochrome c and activation of caspase-3
Casp3↑,
chemoPv↑, potent chemopreventive agent against lung SCC development in a carcinogen-induced lung SCC murine model
OCR↓, HNK treatment results in a decreased oxygen consumption rate (OCR) in whole intact cells, rapidly, and persistently inhibiting mitochondrial respiration, which leads to the induction of apoptosis
mitResp↓,
Apoptosis↑,
RadioS↑, Honokiol as a chemo- and radiosensitizer
NF-kB↓, HNK as an anticancer drug is its potential to inhibit multiple important survival pathways, such as NF-B and Akt
Akt↓,
TNF-α↓, by inhibiting TNF-induced nerve growth factor IB expression in breast cancer cells
PGE2↓, reduced prostaglandin E2 (PGE2) and vascular endothelial growth factor (VEGF) secretion levels
VEGF↓,
NO↝, HNK inhibits cancer cell migration by targeting nitric oxide and cyclooxygenase-2 or Ras GTPase-activating-like protein (IQGAP1) [
COX2↓,
RAS↓,
EMT↓, HNK can reverse the epithelial-mesenchymal-transition (EMT) process, which is a key step during embryogenesis, cancer invasion, and metastasis,
Snail↓, HNK reduced the expression levels of Snail, N-cadherin and -catenin, which are mesenchymal markers, but increased E-cadherin,
N-cadherin↓,
β-catenin/ZEB1↓,
E-cadherin↑,
ER Stress↑, induction of ER stress
p‑STAT3↓, HNK inhibited STAT3 phosphorylation
EGFR↓, inhibiting EGFR phosphorylation and its downstream signaling pathways such as the mTOR signaling pathway
mTOR↓,
mt-ROS↑, We demonstrated that HNK treatment suppresses mitochondrial respiration and increases generation of ROS in the mitochondria, leading to the induction of apoptosis in lung cancer cells
PI3K↓, inhibition of PI3K/Akt/ mTOR, EMT, and Wnt signaling pathways.
Wnt↓,

2884- HNK,    Honokiol inhibits EMT-mediated motility and migration of human non-small cell lung cancer cells in vitro by targeting c-FLIP
- in-vitro, Lung, A549 - in-vitro, Lung, H460
EMT↓, HNK inhibits EMT-mediated motility and migration of human NSCLC cells in vitro by targeting c-FLIP,
cFLIP↓,
N-cadherin↓, increased c-FLIP, N-cadherin (a mesenchymal marker), snail (a transcriptional modulator) and p-Smad2/3 expression, and decreased IκB levels in the cells; these changes were abrogated by co-treatment with HNK (30 μmol/L)
Snail↓,
p‑SMAD2↓,
p‑SMAD3↓,
IKKα↑,
TumCMig↓, HNK inhibits the migration of A549 and H460 cells induced by TNF-α+TGF-β1

2891- HNK,    Honokiol, an Active Compound of Magnolia Plant, Inhibits Growth, and Progression of Cancers of Different Organs
- Review, Var, NA
AntiCan↑, honokiol possesses anti-carcinogenic, anti-inflammatory, anti-oxidative, anti-angiogenic as well as inhibitory effect on malignant transformation of papillomas to carcinomas in vitro and in vivo animal models without any appreciable toxicity.
Inflam↓,
antiOx↑,
selectivity↑,
*toxicity↓,
cycD1/CCND1↓, honokiol resulted in inhibition of UVB-induced expression levels of cyclins (cyclins D1, D2, and E) and CDKs in skin tumors
cycE/CCNE↓,
CDK2↓,
CDK4↓,
TumMeta↓, Honokiol Inhibits Metastatic Potential of Melanoma Cells
NADPH↓, Honokiol not only reduces the NADPH oxidase activity
MMP2↓, honokiol treatment reduces the expression of MMP-2 and MMP-9
MMP9↓,
p‑mTOR↓, honokiol caused significant downregulation of mTOR phosphorylation
EGFR↓, honokiol decreases the expression levels of total EGFR
EMT↓, honokiol effectively inhibits EMT in breast cancer cells
SIRT1↑, onokiol increases the expressions of SIRT1 and SIRT3,
SIRT3↑,
EZH2↓, depletion of EZH2 by honokiol treatment inhibited cell proliferation
Snail↓, significantly down regulates Snail, vimentin, N-cadherin expression, and upregulates cytokeratin-18 and E-cadherin expression
Vim↓,
N-cadherin↓,
E-cadherin↑,
COX2↓, honokiol as an inhibitor of COX-2 expression
NF-kB↓, inhibited transcriptional activity of NF-jB,
*ROS↓, Inhibition of UVR-induced inflammatory mediators as well as ROS by honokiol treatment contributes to the prevention of UVR-induced skin tumor development
Ca+2↑, excessive influx of cytosolic calcium ion into the mitochondria triggers dysfunction of the mitochon- drial membrane permeabilization with mitochondrial ROS induction
ROS↑,

4640- HT,    The anti-cancer potential of hydroxytyrosol
- Review, Var, NA
selectivity↑, Hydroxytyrosol selectively kills cancer cells with minimal impact on normal cells by activating both intrinsic and extrinsic apoptotic pathways.
MMP↓, Disruption of Mitochondrial Membrane Potential
Cyt‑c↑, HT reduces mitochondrial membrane potential (ΔΨm), leading to the release of cytochrome c into the cytoplasm, activating caspase-9 and caspase-3, and triggering an apoptotic cascade (Cancer Letters, 2021).
Casp9↑,
Casp3↑,
Bcl-2↓, It downregulates anti-apoptotic proteins (Bcl-2, Bcl-xL) and upregulates pro-apoptotic proteins (Bax, Bak), promoting mitochondrial outer membrane permeabilization (MPTP opening) (Molecular Oncology, 2022).
BAX↑,
MPT↑,
Fas↑, Activation of Death Receptor-Mediated Extrinsic Apoptotic Pathway: Fas/FasL Pathway
PI3K↓, Suppression of PI3K/Akt/mTOR Pathway
Akt↓,
mTOR↓,
Mcl-1↓, decreases the expression of anti-apoptotic proteins (Mcl-1, Survivin) (Cancer Research, 2021).
survivin↓,
STAT3↓, Blockade of STAT3 Pathway
EMT↓, Hydroxytyrosol blocks key steps of tumor metastasis by regulating epithelial-mesenchymal transition (EMT), cell adhesion, invasion, and angiogenesis.
TumCI↓,
angioG↓,
E-cadherin↑, Upregulation of E-cadherin and Downregulation of N-cadherin
N-cadherin↓,
Snail↓, Inhibition of Snail/Twist Transcription Factors
Twist↓,
MMPs↓, Inhibition of Matrix Metalloproteinases (MMPs)
MMP2↓, HT downregulates the activity of MMP-2 and MMP-9, reducing extracellular matrix (ECM) degradation and inhibiting tumor cell invasion (Cancer Prevention Research, 2021).
MMP9↓,
VEGF↓, Suppression of VEGF/VEGFR Pathway
VEGFR2↓,
Hif1a↓, Degradation of HIF-1α: It inhibits the stabilization of HIF-1α under hypoxic conditions, reducing transcription of downstream pro-angiogenic genes (Molecular Cancer Therapeutics, 2021).
CSCs↓, Inhibition of Tumor Stem Cell Properties
CD44↓, Downregulation of CD44/ALDH1 Markers
Wnt↓, Inhibition of Wnt/β-catenin Pathway
β-catenin/ZEB1↓,

1121- JG,    Juglone suppresses epithelial-mesenchymal transition in prostate cancer cells via the protein kinase B/glycogen synthase kinase-3β/Snail signaling pathway
- in-vitro, Pca, LNCaP
E-cadherin↑,
N-cadherin↓,
Vim↓,
Snail↓,
GSK‐3β↑, prevented inactivation

5115- JG,    Natural Products to Fight Cancer: A Focus on Juglans regia
- Review, Var, NA
Casp3↑, In LNCaP cells, it triggered apoptosis through the intrinsic pathway, promoting the activation of caspases 3 and 9, and decreasing mitochondrial potential (ΔΨ)
Casp9↑,
MMP↓,
AR↓, At sub-toxic concentrations, it downregulated ARs and PSA expression
PSA↓,
E-cadherin↑, Juglone upregulated the expression of the epithelial marker E-cadherin while reducing the mesenchymal factors N-caderin and vimentin.
N-cadherin↓,
Vim↓,
Akt↓, Furthermore, it synergistically inhibited the Akt/glycogen synthase kinase-3β (GSK-3β)/Snail axis that would physiologically promote E-cadherin repression and EMT induction
GSK‐3β↓,
EMT↑,
TumCI↓, decreased cell invasions by 56% and 80%, respectively, on BxPC-3 and PANC-1 cell lines.
MMP9↓, Juglone significantly dropped the protein level of MMP-9 and the vascular endothelial growth factor (VEGF) reporter Phactr-1 in both cell lines, while a drop of MMP-2 was evident only on BxPC-3
VEGF↓,
MMP2↓,
TumCCA↑, juglone promoted G1 cell-cycle arrest [94,95] and ROS-driven apoptosis
ROS↑,
Apoptosis↑,
GSH↓, Glutathione (GSH), catalase (CAT), superoxide dismutase (SOD) and glutathione peroxidase protein levels diminished
Catalase↓,
SOD↓,
GPx↓,
DNAdam↑, juglone cytotoxicity is, at least partially, ascribed to DNA damage
γH2AX↑, high levels of γ-H2AX were registered when juglone was tested in combination with ascorbate.
eff↑, juglone’s anticancer profile (in terms of proliferation inhibition, cytotoxicity, and ROS induction) was highly improved by ascorbate [115], revealing an interesting synergistic activity between these two compounds
BAX↑, upregulation of many proteins involved in the intrinsic and extrinsic pathway, such as Bax, Cyt-c, Fas cell surface death receptor (Fas), Fas-ligand.
Fas↑,
Pin1↓, On U251 glioblastoma cells, juglone arrested cell growth by promoting apoptosis with the involvement of peptidyl-prolyl cis/trans isomerase (Pin1) inhibition [111]. Juglone is a well-known Pin1 inhibitor


Showing Research Papers: 1 to 50 of 91
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* indicates research on normal cells as opposed to diseased cells
Total Research Paper Matches: 91

Pathway results for Effect on Cancer / Diseased Cells:


Redox & Oxidative Stress

antiOx↓, 1,   antiOx↑, 1,   ATF3↑, 1,   Catalase↓, 1,   Copper↑, 1,   ENOX2↓, 1,   Ferroptosis↑, 1,   GPx↓, 1,   GPx4↓, 1,   GSH↓, 3,   GSR↑, 1,   GSTs↓, 1,   HO-1↓, 1,   HO-1↑, 4,   lipid-P↑, 1,   NQO1↑, 2,   NRF2↓, 3,   NRF2↑, 3,   p‑NRF2↓, 1,   OXPHOS↓, 1,   PARK2↑, 1,   ROS↓, 3,   ROS↑, 18,   i-ROS↑, 1,   mt-ROS↑, 1,   SIRT3↑, 2,   SOD↓, 1,   TrxR↓, 1,  

Mitochondria & Bioenergetics

CDC2↓, 2,   CDC25↓, 1,   EGF↓, 1,   MEK↓, 1,   mitResp↓, 3,   MMP↓, 11,   MPT↑, 1,   mtDam↑, 1,   OCR↓, 2,   PINK1↑, 1,   XIAP↓, 2,  

Core Metabolism/Glycolysis

12LOX↓, 1,   ACC↑, 2,   ACLY↓, 1,   AMPK↑, 4,   cMyc↓, 5,   ECAR↓, 1,   FASN↓, 1,   GlucoseCon↓, 1,   Glycolysis↓, 5,   HK2↓, 2,   lactateProd↓, 2,   LDH↓, 1,   LDHA↓, 3,   NADPH↓, 1,   NADPH↑, 1,   PDK1↓, 2,   p‑PDK1↓, 1,   PKM2↓, 1,   PPARγ↓, 1,   RARα↓, 1,   RARβ↑, 1,   RARγ↑, 1,   SIRT1↓, 2,   SIRT1↑, 1,  

Cell Death

Akt↓, 12,   p‑Akt↓, 3,   Apoptosis↑, 9,   ASK1↑, 1,   BAD↑, 3,   Bak↑, 2,   BAX↑, 10,   Bax:Bcl2↑, 1,   Bcl-2↓, 13,   Bcl-xL↓, 2,   BIM↑, 3,   Casp↑, 1,   Casp3↑, 15,   cl‑Casp3↑, 4,   Casp7↑, 1,   Casp8↑, 1,   cl‑Casp8↑, 1,   Casp9↑, 9,   cl‑Casp9↑, 2,   cFLIP↓, 1,   Chk2↓, 1,   Cyt‑c↑, 11,   Diablo↑, 3,   DR5↑, 3,   FADD↑, 1,   Fas↑, 4,   Ferroptosis↑, 1,   HEY1↓, 1,   hTERT/TERT↓, 1,   JNK↑, 2,   MAPK↓, 1,   MAPK↑, 1,   Mcl-1↓, 4,   Myc↓, 1,   p27↑, 2,   p38↓, 1,   p38↑, 2,   p‑p38↓, 1,   survivin↓, 2,   TRAIL↑, 1,   TumCD↑, 1,   YAP/TEAD↓, 1,  

Kinase & Signal Transduction

p70S6↓, 1,   Sp1/3/4↓, 1,  

Transcription & Epigenetics

cJun↓, 3,   EZH2↓, 1,   H19↓, 1,   H3↑, 1,   other↓, 1,  

Protein Folding & ER Stress

CHOP↑, 3,   eIF2α↑, 1,   p‑eIF2α↑, 1,   ER Stress↑, 5,   GRP78/BiP↑, 2,   HSP27↓, 2,   HSP70/HSPA5↓, 3,   HSP90↓, 2,   IRE1↑, 2,   PERK↑, 3,   UPR↑, 1,  

Autophagy & Lysosomes

LC3A↑, 1,   LC3II↑, 1,   p62↓, 2,   TumAuto↑, 2,  

DNA Damage & Repair

CHK1↓, 1,   DNAdam↑, 5,   DNMT1↓, 1,   DNMT3A↓, 1,   P53↑, 5,   p‑P53↑, 1,   ac‑P53↑, 1,   PARP↑, 2,   cl‑PARP↑, 7,   PARP1↑, 1,   PCNA↓, 4,   RAD51↓, 1,   γH2AX↑, 3,   γH2AX↝, 1,  

Cell Cycle & Senescence

CDK1↓, 2,   CDK2↓, 6,   CDK4↓, 6,   Cyc↓, 1,   cycA1/CCNA1↓, 2,   CycB/CCNB1↓, 1,   cycD1/CCND1↓, 7,   cycE/CCNE↓, 3,   P21↑, 4,   p‑RB1↓, 2,   Securin↓, 2,   TAp63α↑, 1,   TumCCA↓, 1,   TumCCA↑, 11,  

Proliferation, Differentiation & Cell State

AXIN1↑, 1,   BMI1↓, 1,   CD133↓, 3,   CD44↓, 3,   CDX2↓, 1,   cFos↓, 3,   CSCs↓, 6,   CSCs↑, 1,   EMT↓, 30,   EMT↑, 1,   EMT↝, 1,   ERK↓, 2,   p‑ERK↓, 2,   FOXO3↑, 2,   Gli1↓, 3,   GSK‐3β↓, 1,   GSK‐3β↑, 1,   p‑GSK‐3β↓, 1,   HDAC↓, 1,   HH↓, 2,   Let-7↑, 1,   LRP6↓, 1,   p‑LRP6↓, 1,   mTOR↓, 9,   mTOR↑, 1,   p‑mTOR↓, 3,   mTORC1↓, 1,   Nanog↓, 2,   NOTCH↓, 2,   NOTCH1↑, 1,   NOTCH3↓, 1,   OCT4↓, 4,   PI3K↓, 6,   p‑PI3K↓, 1,   Pirin↓, 1,   PTEN↑, 2,   RAS↓, 1,   Shh↓, 2,   SHP1↑, 1,   Smo↓, 2,   SOX2↓, 2,   STAT↓, 1,   p‑STAT1↓, 1,   p‑STAT2↓, 1,   STAT3↓, 9,   p‑STAT3↓, 2,   TCF↑, 1,   TOP1↓, 1,   TOP2↓, 1,   TumCG↓, 9,   TumCG↑, 1,   Wnt↓, 6,   Wnt/(β-catenin)↓, 2,  

Migration

AP-1↓, 1,   Ca+2↑, 6,   CAFs/TAFs↓, 1,   E-cadherin↓, 2,   E-cadherin↑, 41,   ER-α36↓, 1,   p‑FAK↓, 1,   Fibronectin↓, 4,   Ki-67↓, 2,   MET↓, 1,   miR-139-5p↑, 1,   miR-19b↓, 1,   miR-301a-3p↓, 1,   MMP1↓, 1,   MMP2↓, 19,   MMP3↓, 1,   MMP7↓, 1,   MMP9↓, 17,   MMPs↓, 2,   N-cadherin↓, 49,   p‑pax↓, 1,   PIR↓, 1,   Rho↓, 1,   ROCK1↓, 2,   Slug↓, 6,   p‑SMAD2↓, 4,   p‑SMAD3↓, 4,   Snail↓, 19,   TET1↑, 1,   TGF-β↓, 1,   TIMP1↓, 1,   TIMP1↑, 1,   TIMP2↓, 1,   TIMP2↑, 1,   TIMP3↑, 1,   TumCI?, 1,   TumCI↓, 21,   TumCMig↓, 22,   TumCP↓, 9,   TumCP↑, 1,   TumMeta↓, 11,   Twist↓, 6,   uPA↓, 5,   Vim↓, 30,   Zeb1↓, 5,   ZEB2↓, 2,   ZO-1↑, 5,   β-catenin/ZEB1↓, 11,  

Angiogenesis & Vasculature

angioG↓, 5,   ATF4↓, 1,   ATF4↑, 3,   EGFR↓, 5,   eNOS↓, 1,   HIF-1↓, 1,   Hif1a↓, 6,   NO↑, 1,   NO↝, 1,   PDGFR-BB↓, 1,   VEGF↓, 13,   VEGFR2↓, 2,  

Barriers & Transport

BBB↓, 1,  

Immune & Inflammatory Signaling

COX2↓, 8,   IKKα↓, 1,   IKKα↑, 1,   IL1β↓, 1,   IL6↓, 3,   Inflam↓, 2,   p‑JAK↓, 1,   p‑JAK2↓, 1,   p‑JAK3↓, 1,   NF-kB↓, 11,   NF-kB↑, 1,   p‑NF-kB↓, 1,   p65↓, 1,   p‑p65↓, 1,   PD-L1↓, 2,   PGE2↓, 4,   PSA↓, 2,   TNF-α↓, 2,  

Hormonal & Nuclear Receptors

AR↓, 1,   CDK6↓, 1,  

Drug Metabolism & Resistance

BioAv↓, 2,   BioAv↑, 2,   ChemoSen↑, 9,   Dose↝, 2,   Dose∅, 2,   eff↓, 1,   eff↑, 17,   Half-Life↝, 1,   RadioS↑, 5,   selectivity↑, 4,  

Clinical Biomarkers

AFP↓, 1,   AR↓, 1,   E6↓, 1,   E7↓, 1,   EGFR↓, 5,   EZH2↓, 1,   hTERT/TERT↓, 1,   IL6↓, 3,   Ki-67↓, 2,   LDH↓, 1,   Myc↓, 1,   PD-L1↓, 2,   PSA↓, 2,  

Functional Outcomes

AntiCan↑, 2,   AntiTum↑, 2,   chemoPv↑, 2,   hepatoP↑, 1,   neuroP↑, 1,   OS↑, 2,   Pin1↓, 1,   RenoP↑, 1,   TumVol↓, 3,   TumW↓, 2,  
Total Targets: 322

Pathway results for Effect on Normal Cells:


Redox & Oxidative Stress

antiOx↓, 1,   antiOx↑, 4,   Catalase↑, 2,   GPx↑, 2,   GSH↑, 2,   GSR↑, 1,   HO-1↑, 2,   lipid-P↓, 1,   MDA↓, 1,   NRF2↑, 4,   Prx↑, 1,   ROS↓, 3,   SOD↑, 2,   SOD2↑, 1,  

Core Metabolism/Glycolysis

ALAT↓, 1,   AMPK↑, 2,   p‑cMyc↑, 1,   glucose↓, 1,   LDH↓, 2,   lipidLev↓, 1,   PPARα↝, 1,   p‑PPARγ↓, 1,  

Cell Death

Akt↓, 1,   Casp↓, 1,   Casp3?, 1,   JNK↓, 1,  

Proliferation, Differentiation & Cell State

ERK↑, 1,   PI3K↓, 1,  

Migration

Ca+2↓, 1,   Ca+2↝, 1,   cal2↓, 1,   E-cadherin↑, 1,   F-actin↓, 1,   N-cadherin↓, 1,   Snail↓, 1,   TRPC1↓, 1,   TumCMig↓, 1,   Vim↓, 1,   ZO-1↑, 1,  

Angiogenesis & Vasculature

Hif1a↓, 1,  

Immune & Inflammatory Signaling

COX2↓, 1,   IL18↓, 1,   IL1β↓, 1,   IL2↓, 1,   IL6↓, 2,   IL8↓, 1,   Inflam↓, 4,   NF-kB↓, 2,   TLR4↓, 1,   TNF-α↓, 3,  

Synaptic & Neurotransmission

AChE↓, 1,  

Protein Aggregation

Aβ↓, 1,  

Drug Metabolism & Resistance

BioAv↓, 1,   BioAv↝, 1,   Dose↑, 1,   eff↑, 1,   Half-Life↝, 2,  

Clinical Biomarkers

ALAT↓, 1,   ALP↓, 1,   AST↓, 1,   BP↓, 1,   IL6↓, 2,   LDH↓, 2,  

Functional Outcomes

AntiDiabetic↑, 1,   cardioP↑, 3,   chemoPv↑, 1,   cognitive↑, 1,   hepatoP↑, 2,   memory↑, 1,   neuroP↑, 4,   RenoP↑, 1,   toxicity↓, 2,  
Total Targets: 72

Scientific Paper Hit Count for: N-cadherin, N-cadherin
8 Curcumin
5 Resveratrol
5 Luteolin
5 Quercetin
4 Fisetin
4 Honokiol
4 Thymoquinone
3 Artemisinin
3 Baicalein
3 Urolithin
2 Astragalus
2 Ashwagandha(Withaferin A)
2 Berberine
2 Betulinic acid
2 Chlorogenic acid
2 Grapeseed extract
2 Juglone
2 Piperlongumine
2 Rosmarinic acid
2 Sulforaphane (mainly Broccoli)
2 Silymarin (Milk Thistle) silibinin
2 Ursolic acid
1 Allicin (mainly Garlic)
1 Cisplatin
1 Apigenin (mainly Parsley)
1 Astaxanthin
1 Baicalin
1 Biochanin A
1 Butyrate
1 Capsaicin
1 Carvacrol
1 Cannabidiol
1 Chrysin
1 Cyclopamine
1 Oxaliplatin
1 Emodin
1 Ginger/6-Shogaol/Gingerol
1 Proanthocyanidins
1 HydroxyTyrosol
1 Lycopene
1 Magnolol
1 Oroxylin A
1 Phenylbutyrate
1 Phenethyl isothiocyanate
1 Piperine
1 salinomycin
1 Shikonin
1 Selenite (Sodium)
1 Taurine
1 VitK3,menadione
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#:355  State#:%  Dir#:1
  wNotes=on  sortOrder:rid,rpid

 

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