FasL Cancer Research Results

FasL, Fas ligand: Click to Expand ⟱
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Fas ligand (FasL) is a protein that plays a crucial role in the regulation of the immune system and programmed cell death, also known as apoptosis. In the context of cancer, FasL has been found to have both tumor-promoting and tumor-suppressing effects.
FasL is upregulated in melanoma, colon.
FasL: tumor suppressing effect on Breast and Lung cancer.

FasL inhibitors, which block the interaction between Fas and FasL, have been shown to enhance the effectiveness of chemotherapy and immunotherapy
Scientific Papers found: Click to Expand⟱
1524- Ba,    Baicalein Induces Caspase‐dependent Apoptosis Associated with the Generation of ROS and the Activation of AMPK in Human Lung Carcinoma A549 Cells
- in-vitro, Lung, A549
DR5↑, Baicalein stimulated the expression of DR5, FasL, and FADD, and activated caspase‐8
FADD↑,
FasL↑,
Casp8↑,
cFLIP↓, reducing the levels of FLIPs
Casp3↑, activation of caspase‐9 and −3, and cleavage of poly(ADP‐ribose) polymerase
Casp9↑,
cl‑PARP↑,
MMP↓, baicalein caused a mitochondrial membrane potential (MMP),
BID↑, the truncation of Bid (means that the protein has been converted into an active form (tBid) that supports apoptosis.)
Cyt‑c↑, inducing the release of cytochrome c into the cytosol
ROS↑, baicalein increased the generation of reactive oxygen species (ROS)
eff↓, however, an ROS scavenger, N‐acetylcysteine, notably attenuated baicalein‐mediated loss of MMP and activation of caspases
AMPK↑,
Apoptosis↑,
TumCCA↑, sub-G1 phase
DR5↑, baicalein increased the expression of DR5 and FasL in a concentration-dependent manner, whereas the levels of DR4
FasL↑,
DR4∅,
cFLIP↓, baicalein reduced both FLIP(L) and FLIP(S) protein levels
FADD↑, increased FADD expression
MMPs↓, baicalein treatment reduced MMP levels in a concentrationdependent manner

1521- Ba,    Baicalein induces apoptosis via ROS-dependent activation of caspases in human bladder cancer 5637 cells
- in-vitro, Bladder, 5637
TumCG↓,
Apoptosis↑,
IAP1↓, downregulation of members of the inhibitor of apoptosis protein (IAP) family, including cIAP-1 and cIAP-2,
IAP2↓,
Casp3↑, activation of caspase-9 and -3
Casp9↑,
BAX↑,
Bcl-2↓,
MMP↓, dose-dependent loss of MMP
Casp8↑,
BID↑,
ROS?, baicalein can induce the production of reactive oxygen species (ROS) hese findings suggest that an increase in ROS is required for the occurrence of baicalein- induced apoptosis in 5637 cells.
eff↓, pretreatment with the antioxidant N-acetyl-L-cysteine significantly attenuates the baicalein effects on the loss of MMP and activation of caspase
DR4↑, baicalein considerably increased the levels of DR4, DR5, FasL, and TRAIL.
DR5↑,
FasL↑,
TRAIL↑,

2476- Ba,    Baicalein Induces Caspase-dependent Apoptosis Associated with the Generation of ROS and the Activation of AMPK in Human Lung Carcinoma A549 Cells
- in-vitro, Lung, A549
TumCG↓, baicalein-induced growth inhibition was associated with the induction of apoptosis in human lung carcinoma A549 cells.
Apoptosis↑,
DR5↑, Baicalein stimulated the expression of DR5, FasL, and FADD, and activated caspase-8 by reducing the levels of FLIPs (FLICE-inhibitory proteins).
FasL↑,
FADD↑,
Casp8↑,
cFLIP↓,
Casp9↑, activation of caspase-9 and -3, and cleavage of poly(ADP-ribose) polymerase
Casp3↑,
cl‑PARP↑,
MMP↓, Additionally, baicalein caused a mitochondrial membrane potential (MMP), the truncation of Bid, and the translocation of pro-apoptotic Bax to the mitochondria, thereby inducing the release of cytochrome c into the cytosol.
BID↑,
BAX↑,
Cyt‑c↑,
ROS↑, In turn, baicalein increased the generation of reactive oxygen species (ROS)
eff↓, however, an ROS scavenger, N-acetylcysteine, notably attenuated baicalein-mediated loss of MMP and activation of caspases.
AMPK↑, connected with ROS generation and AMPK activation.

2691- BBR,    Berberine induces FasL-related apoptosis through p38 activation in KB human oral cancer cells
- in-vitro, Oral, KB
tumCV↓, viability of KB cells was found to decrease significantly in the presence of berberine in a dose-dependent manner.
DNAdam↑, berberine induced the fragmentation of genomic DNA, changes in cell morphology, and nuclear condensation.
Casp3↑, caspase-3 and -7 activation, and an increase in apoptosis were observed.
Casp7↑,
FasL↑, Berberine was also found to upregulate significantly the expression of the death receptor ligand, FasL
Casp8↑, triggered the activation of pro-apoptotic factors such as caspase-8, -9 and -3 and poly(ADP-ribose) polymerase (PARP).
Casp9↑,
PARP↑,
BAX↑, Bax, Bad and Apaf-1 were also significantly upregulated by berberine.
BAD↑,
APAF1↑,
MMP2↓, We also found that berberine-induced migration suppression was mediated by downregulation of MMP-2 and MMP-9 through phosphorylation of p38 MAPK.
MMP9↓,
p‑p38↑, This suggests that berberine-induced activation of the p38 and ERK1/2 MAPK pathways is the principal pathway involved in the apoptosis mediated by berberine in KB cells.
ERK↑,
MAPK↑,

2674- BBR,    Berberine: A novel therapeutic strategy for cancer
- Review, Var, NA - Review, IBD, NA
Inflam↓, anti-inflammatory, antidiabetic, antibacterial, antiparasitic, antidiarrheal, antihypertensive, hypolipidemic, and fungicide.
AntiCan↑, elaborated on the anticancer effects of BBR through the regulation of different molecular pathways such as: inducing apoptosis, autophagy, arresting cell cycle, and inhibiting metastasis and invasion.
Apoptosis↑,
TumAuto↑,
TumCCA↑,
TumMeta↓,
TumCI↓,
eff↑, BBR is shown to have beneficial effects on cancer immunotherapy.
eff↑, BBR inhibited the release of Interleukin 1 beta (IL-1β), Interferon gamma (IFN-γ), Interleukin 6 (IL-6), and Tumor Necrosis Factor-alpha (TNF-α) from LPS stimulated lymphocytes by acting as a dopamine receptor antagonist
CD4+↓, BBR inhibited the proliferation of CD4+ T cells and down-regulated TNF-α and IL-1 and thus, improved autoimmune neuropathy.
TNF-α↓,
IL1↓,
BioAv↓, On the other hand, P-Glycoprotein (P-gp), a secretive pump located in the epithelial cell membrane, restricts the oral bioavailability of a variety of medications, such as BBR. The use of P-gp inhibitors is a common and effective way to prevent this
BioAv↓, Regardless of its low bioavailability, BBR has shown great therapeutic efficacy in the treatment of a number of diseases.
other↓, BBR has been also used as an effective therapeutic agent for Inflammatory Bowel Disease (IBD) for several years
AMPK↑, inhibitory effects on inflammation by regulating different mechanisms such as 5′ Adenosine Monophosphate-Activated Protein Kinase (AMPK. Increase of AMPK
MAPK↓, Mitogen-Activated Protein Kinase (MAPK), and NF-κB signaling pathways
NF-kB↓,
IL6↓, inhibiting the expression of proinflammatory genes such as IL-1, IL-6, Monocyte Chemoattractant Protein 1 (MCP1), TNF-α, Prostaglandin E2 (PGE2), and Cyclooxygenase-2 (COX-2)
MCP1↓,
PGE2↓,
COX2↓,
*ROS↓, BBR protected PC-12 cells (normal) from oxidative damage by suppressing ROS through PI3K/AKT/mTOR signaling pathways
*antiOx↑, BBR therapy improved the antioxidant function of mice intestinal tissue by enhancing the levels of glutathione peroxidase and catalase enzymes.
*GPx↑,
*Catalase↑,
AntiTum↑, Besides, BBR leaves great antitumor effects on multiple types of cancer such as breast cancer,69 bladder cancer,70 hepatocarcinoma,71 and colon cancer.72
TumCP↓, BBR exerts its antitumor activity by inhibiting proliferation, inducing apoptosis and autophagy, and suppressing angiogenesis and metastasis
angioG↓,
Fas↑, by increasing the amounts of Fas receptor (death receptor)/FasL (Fas ligand), ROS, ATM, p53, Retinoblastoma protein (Rb), caspase-9,8,3, TNF-α, Bcl2-associated X protein (Bax), BID
FasL↑,
ROS↑,
ATM↑,
P53↑,
RB1↑,
Casp9↑,
Casp8↑,
Casp3↓,
BAX↑,
Bcl-2↓, and declining Bcl2, Bcl-X, c-IAP1 (inhibitor of apoptosis protein), X-linked inhibitor of apoptosis protein (XIAP), and Survivin levels
Bcl-xL↓,
IAP1↓,
XIAP↓,
survivin↓,
MMP2↓, Furthermore, BBR suppressed Matrix Metalloproteinase-2 (MMP-2), and MMP-9 expression.
MMP9↓,
CycB/CCNB1↓, Inhibition of cyclin B1, cdc2, cdc25c
CDC25↓,
CDC25↓,
Cyt‑c↑, BBR inhibited tumor cell proliferation and migration and induced mitochondria-mediated apoptosis pathway in Triple Negative Breast Cancer (TNBC) by: stimulating cytochrome c release from mitochondria to cytosol
MMP↓, decreased the mitochondrial membrane potential, and enabled cytochrome c release from mitochondria to cytosol
RenoP↑, BBR significantly reduced the destructive effects of cisplatin on the kidney by inhibiting autophagy, and exerted nephroprotective effects.
mTOR↓, U87 cell, Inhibition of m-TOR signaling
MDM2↓, Downregulation of MDM2
LC3II↑, Increase of LC3-II and beclin-1
ERK↓, BBR stimulated AMPK signaling, resulting in reduced extracellular signal–regulated kinase (ERK) activity and COX-2 expression in B16F-10 lung melanoma cells
COX2↓,
MMP3↓, reducing MMP-3 in SGC7901 GC and AGS cells
TGF-β↓, BBR suppressed the invasion and migration of prostate cancer PC-3 cells by inhibiting TGF-β-related signaling molecules which induced Epithelial-Mesenchymal Transition (EMT) such as Bone morphogenetic protein 7 (BMP7),
EMT↑,
ROCK1↓, inhibiting metastasis-associated proteins such as ROCK1, FAK, Ras Homolog Family Member A (RhoA), NF-κB and u-PA, leading to in vitro inhibition of MMP-1 and MMP-13.
FAK↓,
RAS↓,
Rho↓,
NF-kB↓,
uPA↓,
MMP1↓,
MMP13↓,
ChemoSen↑, recent studies have indicated that it can be used in combination with chemotherapy agents

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.

5943- Cela,    Celastrol: A Spectrum of Treatment Opportunities in Chronic Diseases
- Review, Arthritis, NA - Review, IBD, NA - Review, AD, NA - Review, Park, NA
*other↝, The most abundant and promising bioactive compound derived from the root of this plant is celastrol, also called tripterine, which possess a broad range of biological activities
*other↝, TW is generally used in the treatment of Crohn’s disease (CD) in China.
*CRP↓, Inflammatory parameters, including c-reactive protein (CRP), also decreased
*eff↝, Etanercept plus TW had an equivalent therapeutic effect to that of Etanercept plus MTX and were both well tolerated
*other↑, TW in human kidney transplantation (26). Rejection occurred in 4.1% of patients treated with TW versus 24.5% of control patients, showing efficacy in the prevention of renal allograph rejection
*CXCR4↓, celastrol decreases hypoxia-induced FLS invasion by inhibiting HIF-1α-mediated CXCR4 transcription
*IL1β↓, Authors have shown that it decreases the production of IL-1β, IL-6, IL-17, IL-18, and TNF by SIC cells harvested from arthritic rats
*IL6↓,
*IL17↓,
*IL18↓,
*TNF-α↓,
*MMP9↓, celastrol reduces MMP-9 production, which limits bone damage
*PGE2↓, celastrol suppresses LPS-induced expression of PEG2 via the downregulation of COX-1 and COX-2 activation
*COX1↓,
*COX2↓,
*PI3K↓, associated with a decrease in PI3K/Akt pathway
*Akt↓,
*other↑, Remarkably, this bone-protective property of celastrol in arthritic models is further supported by studies performed in cancer models
TumCCA↑, celastrol induces cell cycle arrest, apoptosis, and autophagy by the activation of reactive oxygen species (ROS)/c-Jun N-terminal kinases (JNK) signaling pathway
Apoptosis↑,
ROS↑,
JNK↑,
TumAuto↑, celastrol is still able to induce autophagy through HIF/BNIP3 activation
Hif1a↓, The inhibitory effect of celastrol on angiogenesis is mediated by the suppression of HIF-1α,
BNIP3↝,
HSP90↓, The inhibition of HSP90 by celastrol
Fas↑, activation of Fas/Fas ligand pathway in non-small-cell lung cancer
FasL↑,
ETC↓, inhibition of mitochondrial respiratory chain (MRC) complex I
VEGF↓, This inhibition of HIF-1α leads to the decrease of its target genes, such as the VEGF
angioG↓, Angiogenesis Inhibition
RadioS↑, celastrol can overcome tumor resistance to radiotherapy in prostate (129) and lung cancer cells
*neuroP↑, celastrol is a promising neuroprotective agent in animal models of neurodegenerative diseases, such as Parkinson disease (149), Huntington disease (149–151), Alzheimer disease
*HSP70/HSPA5↑, his induction of HSP70 by celastrol explains its beneficial effects not only in neurodegenerative disorders but also in inflammatory diseases.
*ROS↓, celastrol protects human dopaminergic cells from injury and apoptosis and prevents ROS generation and mitochondrial membrane potential loss
*MMP↑,
*Cyt‑c↓, It inhibits cytochrome c release, Bax/Bcl-2 alterations, caspase-9/3 activation, and p38 MAPK activation
*Casp3↓,
*Casp9↓,
*MAPK↓,
*Dose⇅, Authors discuss that it seems to have a narrow therapeutic window, and suggest that it may have a biphasic effect with protective properties at low concentrations and toxic effects at higher concentrations.
*HSPs↑, induces a set of HSPs (HSP27, 32, and 70) in rat cerebral cortical cultures, which are selectively impacted during the progression of this disease
BioAv↓, Due to this poor water solubility, celastrol has low bioavailability. oral administration of celastrol in rats results in ineffective absorption into the systemic circulation, with an absolute bioavailability of 17.06%
Dose↝, narrow therapeutic window of dose together with the occurrence of adverse effects. Our own data showed in vivo that the doses of 2.5 and 5 μg/g/day are effective and non-toxic in the treatment of arthritis in rats;

4493- Chit,  Selenate,  Se,    A novel synthetic chitosan selenate (CS) induces apoptosis in A549 lung cancer cells via the Fas/FasL pathway
- in-vitro, Lung, A549
tumCV↓, CS could significantly inhibit A549 cells viability in a dose-dependent manner.
Apoptosis↑, CS induced cell death via apoptosis and not necrosis.
TumCCA↑, CS triggered S and G2/M phase arrest in a dose-dependent manner
Fas↑, CS up-regulated the expression levels of Fas, FasL, and Fadd
FasL↑,
FADD↑,
Casp↑, activated the caspase cascade in A549 cells

1145- CHr,    Chrysin inhibits propagation of HeLa cells by attenuating cell survival and inducing apoptotic pathways
- in-vitro, Cerv, HeLa
tumCV↓,
BAX↑,
BID↑,
BOK↑,
APAF1↑,
TNF-α↑,
FasL↑,
Fas↑,
FADD↑,
Casp3↑,
Casp7↑,
Casp8↑,
Casp9↑,
Mcl-1↓,
NAIP↓,
Bcl-2↓,
CDK4↓,
CycB/CCNB1↓,
cycD1/CCND1↓,
cycE1↓,
TRAIL↑,
p‑Akt↓,
Akt↓,
mTOR↓,
PDK1↓,
BAD↓,
GSK‐3β↑,
AMPK↑, AMPKa
p27↑,
P53↑,

4455- DFE,    Ajwa Date (Phoenix dactylifera L.) Extract Inhibits Human Breast Adenocarcinoma (MCF7) Cells In Vitro by Inducing Apoptosis and Cell Cycle Arrest
- in-vitro, BC, MCF-7 - in-vitro, Nor, 3T3
TumCCA↑, demonstrated cell cycle arrest at 'S' phase; increased p53, Bax protein expression; caspase 3activation and decreased the mitochondrial membrane potential (MMP)
P53↑,
BAX↑,
Casp3↑,
MMP↓,
Fas↑, Quantitative real time PCR (qRT-PCR) analysis showed up-regulation of p53, Bax, Fas, and FasL and down-regulation of Bcl-2.
FasL↑,
Bcl-2↓,
Apoptosis↑, MEAD inhibited MCF7 cells in vitro by the inducing cell cycle arrest and apoptosis
TumCP↓, MEAD inhibited MCF7 proliferation
TUNEL↑, MEAD for 48 h showed dose dependent increase in the numbers of TUNEL positive cells compared to the untreated control
eff↑, Given the folklore claims of cancer inhibitory properties of Ajwa date extract and our results on MCF7 cells, the date fruits could be added daily as a nutritional supplement for synergistic chemopreventive effects against breast cancer and other mal
selectivity↑, IC50, 50 mg/ml vs 18.2 mg/ml

5152- GamB,    Gambogic Acid as a Candidate for Cancer Therapy: A Review
- Review, Var, NA
AntiCan↑, GA has obvious anti-cancer effects via various molecular mechanisms, including the induction of apoptosis, autophagy, cell cycle arrest and the inhibition of invasion, metastasis, angiogenesis.
Apoptosis↑,
TumAuto↑,
TumCCA↑,
TumCI↓,
TumMeta↓,
angioG↓,
eff↑, In order to improve the efficacy in cancer treatment, nanometer drug delivery systems have been employed to load GA and form micelles, nanoparticles, nanofibers
NF-kB↓, GA could inhibit the activation of NF-κB
P53↑, GA increases p53 expression via down-regulating MDM2 in wild type p53 expressing human cancer cells (non-small cell lung H1299)
P21↑, GA could enhance p21Waf1/CIP1 expression to induce cell apoptosis in human breast cancer cells (MCF-7) via suppressing MDM2
MDM2↓,
HSP90↓, GA was considered as a natural product inhibitor of Hsp90
Bcl-2↓, bcl-2 reduction is associated with the release of cytochrome c, leading to an apoptosis cascade reaction
Cyt‑c↑,
Casp↑,
MMP↓, rapid mitochondrial membrane depolarization and fragmentation
Casp3↑, activation of caspase-3, 9 and cleaved PARP and increased ratio of bax/bcl-2.
Casp9↑,
cl‑PARP↑,
Bax:Bcl2↑,
ROS↑, GA-induced reactive oxygen species (ROS) may be the cause of the collapse of mitochondrial transmembrane potential, which could also down-regulate SIRT1 in multiple myeloma
SIRT1↓,
TrxR1↓, GA may also interact with the thioredoxin reductase 1 (TrxR1) to elicit oxidative stress leading to ROS accumulation in hepatocellular carcinoma
Fas↓, GA with increased death receptor (Fas, FasL, Fas-associated protein with death domain (FADD) and Apaf-1) and deoxyribonucleic acid (DNA) fragmentation.
FasL↑,
FADD↑,
APAF1↑,
DNAdam↑,
NF-kB↓, GA could inhibit NF-κB pathway through suppressing IκBα and p65 phosphorylation
STAT3↓, GA also suppressed the signal transducer and activator of transcription (STAT3) phosphorylation to induce cell apoptosis
MAPK↓, GA induced cell apoptosis via suppression of mitogen-activated protein kinases (MAPK) pathway and c-fos
cFos↓,
EGFR↓, GA could also enhance epidermal growth factor receptor (EGFR) degradation and inhibit AKT/mTOR complex 1 (mTORC1) via up-regulating AMP-activated protein kinase (AMPK)-
Akt↓,
mTOR↓,
AMPK↑,
TumCCA↑, GA could obviously induce G2/M or G0/G1 arrest in various cancer cell lines, such as MCF-7 cells, K562 cells, U2OS cells, and so on
ChemoSen↑, GA distinctly sensitized doxorubicin (DOX)-resistant breast cancer cells through inhibiting P-glycoprotein and suppressing the survivin expression revealed by ROS-mediated activation of the p38 MAPK
P-gp↓,
survivin↓,

2919- LT,    Luteolin as a potential therapeutic candidate for lung cancer: Emerging preclinical evidence
- Review, Var, NA
RadioS↑, it can be used as an adjuvant to radio-chemotherapy and helps to ameliorate cancer complications
ChemoSen↑,
chemoP↑,
*lipid-P↓, ↓LPO, ↑CAT, ↑SOD, ↑GPx, ↑GST, ↑GSH, ↓TNF-α, ↓IL-1β, ↓Caspase-3, ↑IL-10
*Catalase↑,
*SOD↑,
*GPx↑,
*GSTs↑,
*GSH↑,
*TNF-α↓,
*IL1β↓,
*Casp3↓,
*IL10↑,
NRF2↓, Lung cancer model ↓Nrf2, ↓HO-1, ↓NQO1, ↓GSH
HO-1↓,
NQO1↓,
GSH↓,
MET↓, Lung cancer model ↓MET, ↓p-MET, ↓p-Akt, ↓HGF
p‑MET↓,
p‑Akt↓,
HGF/c-Met↓,
NF-kB↓, Lung cancer model ↓NF-κB, ↓Bcl-XL, ↓MnSOD, ↑Caspase-8, ↑Caspase-3, ↑PARP
Bcl-2↓,
SOD2↓,
Casp8↑,
Casp3↑,
PARP↑,
MAPK↓, LLC-induced BCP mouse model ↓p38 MAPK, ↓GFAP, ↓IBA1, ↓NLRP3, ↓ASC, ↓Caspase1, ↓IL-1β
NLRP3↓,
ASC↓,
Casp1↓,
IL6↓, Lung cancer model ↓TNF‑α, ↓IL‑6, ↓MuRF1, ↓Atrogin-1, ↓IKKβ, ↓p‑p65, ↓p-p38
IKKα↓,
p‑p65↓,
p‑p38↑,
MMP2↓, Lung cancer model ↓MMP-2, ↓ICAM-1, ↓EGFR, ↓p-PI3K, ↓p-Akt
ICAM-1↓,
EGFR↑,
p‑PI3K↓,
E-cadherin↓, Lung cancer model ↑E-cadherin, ↑ZO-1, ↓N-cadherin, ↓Claudin-1, ↓β-Catenin, ↓Snail, ↓Vimentin, ↓Integrin β1, ↓FAK
ZO-1↑,
N-cadherin↓,
CLDN1↓,
β-catenin/ZEB1↓,
Snail↓,
Vim↑,
ITGB1↓,
FAK↓,
p‑Src↓, Lung cancer model ↓p-FAK, ↓p-Src, ↓Rac1, ↓Cdc42, ↓RhoA
Rac1↓,
Cdc42↓,
Rho↓,
PCNA↓, Lung cancer model ↓Cyclin B1, ↑p21, ↑p-Cdc2, ↓Vimentin, ↓MMP9, ↑E-cadherin, ↓AIM2, ↓Pro-caspase-1, ↓Caspase-1 p10, ↓Pro-IL-1β, ↓IL-1β, ↓PCNA
Tyro3↓, Lung cancer model ↓TAM RTKs, ↓Tyro3, ↓Axl, ↓MerTK, ↑p21
AXL↓,
CEA↓, B(a)P induced lung carcinogenesis ↓CEA, ↓NSE, ↑SOD, ↑CAT, ↑GPx, ↑GR, ↑GST, ↑GSH, ↑Vitamin E, ↑Vitamin C, ↓PCNA, ↓CYP1A1, ↓NF-kB
NSE↓,
SOD↓,
Catalase↓,
GPx↓,
GSR↓,
GSTs↓,
GSH↓,
VitE↓,
VitC↓,
CYP1A1↓,
cFos↑, Lung cancer model ↓Claudin-2, ↑p-ERK1/2, ↑c-Fos
AR↓, ↓Androgen receptor
AIF↑, Lung cancer model ↑Apoptosis-inducing factor protein
p‑STAT6↓, ↓p-STAT6, ↓Arginase-1, ↓MRC1, ↓CCL2
p‑MDM2↓, Lung cancer model ↓p-PI3K, ↓p-Akt, ↓p-MDM2, ↑p-P53, ↓Bcl-2, ↑Bax
NOTCH1↓, Lung cancer model ↑Bax, ↑Cleaved-caspase 3, ↓Bcl2, ↑circ_0000190, ↓miR-130a-3p, ↓Notch-1, ↓Hes-1, ↓VEGF
VEGF↓,
H3↓, Lung cancer model ↑Caspase 3, ↑Caspase 7, ↓H3 and H4 HDAC activities
H4↓,
HDAC↓,
SIRT1↓, Lung cancer model ↑Bax/Bcl-2, ↓Sirt1
ROS↑, Lung cancer model ↓NF-kB, ↑JNK, ↑Caspase 3, ↑PARP, ↑ROS, ↓SOD
DR5↑, Lung cancer model ↑Caspase-8, ↑Caspase-3, ↑Caspase-9, ↑DR5, ↑p-Drp1, ↑Cytochrome c, ↑p-JNK
Cyt‑c↑,
p‑JNK↑,
PTEN↓, Lung cancer model 1/5/10/30/50/80/100 μmol/L ↑Cleaved caspase-3, ↑PARP, ↑Bax, ↓Bcl-2, ↓EGFR, ↓PI3K/Akt/PTEN/mTOR, ↓CD34, ↓PCNA
mTOR↓,
CD34↓,
FasL↑, Lung cancer model ↑DR 4, ↑FasL, ↑Fas receptor, ↑Bax, ↑Bad, ↓Bcl-2, ↑Cytochrome c, ↓XIAP, ↑p-eIF2α, ↑CHOP, ↑p-JNK, ↑LC3II
Fas↑,
XIAP↓,
p‑eIF2α↑,
CHOP↑,
LC3II↑,
PD-1↓, Lung cancer model ↓PD-L1, ↓STAT3, ↑IL-2
STAT3↓,
IL2↑,
EMT↓, Luteolin exerts anticancer activity by inhibiting EMT, and the possible mechanisms include the inhibition of the EGFR-PI3K-AKT and integrin β1-FAK/Src signaling pathways
cachexia↓, luteolin could be a potential safe and efficient alternative therapy for the treatment of cancer cachexi
BioAv↑, A low-energy blend of castor oil, kolliphor and polyethylene glycol 200 increases the solubility of luteolin by a factor of approximately 83
*Half-Life↝, ats administered an intraperitoneal injection of luteolin (60 mg/kg) absorbed it rapidly as well, with peak levels reached at 0.083 h (71.99 ± 11.04 μg/mL) and a prolonged half-life (3.2 ± 0.7 h)
*eff↑, Luteolin chitosan-encapsulated nano-emulsions increase trans-nasal mucosal permeation nearly 6-fold, drug half-life 10-fold, and biodistribution of luteolin in brain tissue 4.4-fold after nasal administration

5217- PG,    Role of redox signaling regulation in propyl gallate-induced apoptosis of human leukemia cells
- in-vitro, AML, THP1 - in-vitro, AML, Jurkat - in-vitro, AML, HL-60
tumCV↓, PG reduced cell viability in THP-1, Jurkat, and HL-60 leukemia cells and induced apoptosis in THP-1 cells.
Casp3↑, PG activated caspases 3, 8, and 9 and increased the levels of p53, Bax, Fas, and Fas ligand
Casp8↑,
Casp9↑,
P53↑,
BAX↑,
Fas↑,
FasL↑,
MAPK↑, PG activated mitogen-activated protein kinases (MAPKs), inhibited nuclear translocation of the nuclear factor erythroid 2-related factor 2 (Nrf-2) and induced intracellular glutathione (GSH) depletion.
NRF2↓,
GSH↓,

2005- PLB,    Plumbagin induces apoptosis in lymphoma cells via oxidative stress mediated glutathionylation and inhibition of mitogen-activated protein kinase phosphatases (MKP1/2)
- in-vivo, Nor, EL4 - in-vitro, AML, Jurkat
JNK↑, Plumbagin induced persistent activation of JNK
Cyt‑c↑, plumbagin induced cytochrome c release, FasL expression and Bax levels via activation of JNK pathway
FasL↑,
BAX↑,
ROS↑, plumbagin has been reported to induce ROS in normal as well as in tumor cells
*ROS↑, induce ROS in normal as well as in tumor cells
MKP1↓, plumbagin induced oxidative stress may suppress MKP activity in lymphoma cells leading to sustained JNK activation resulting in apoptosis.
MKP2↓,
selectivity∅, Plumbagin induced cell death in EL4(normal) cells and Jurkat cells
tumCV↑, cell viability dramatically decreased with increasing concentrations of plumbagin (0.05-2.5uM) when incubated for 24 or 48 h
Cyt‑c↑, Bax dependent cytochrome c release and apoptosome complex formation is followed by the cleavage of pro-caspase-3
Casp3↑,
GSH/GSSG↓, progressive decrease in GSH/GSSG ratio in tumor cells following plumbagin treatment
ROS↑, simultaneous increase in the levels of intracellular ROS was observed in both these cell lines which remained high up to 4 h indicating an increase in oxidative stress in tumor cells
mt-ROS↑, While we observed low basal mtROS levels in untreated cells, plumbagin treatment resulted in a significant increase in mtROS levels
*ROS↑, both cell lines, meaning normal EL4 cells too
eff↓, NAC, GSH and PEG-catalase were able to abrogate plumbagin induced ROS and cell death.

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

4486- Se,  Chit,    Selenium-Modified Chitosan Induces HepG2 Cell Apoptosis and Differential Protein Analysis
- in-vitro, Liver, HepG2
Apoptosis↑, selenium-modified chitosan (SMC)can induce HepG2 cell apoptosis with the cell cycle arrested in the S and G2/M phases
TumCCA↑,
MMP↓, gradual disruption of mitochondrial membrane potential
Bcl-2↓, reduce the expression of Bcl2, and improve the expression of Bax, cytochrome C, cleaved caspase 9, and cleaved caspase 3
BAX↑,
cl‑Casp9↑,
cl‑Casp3↑,
Risk↓, Relevant research suggests that an inverse relationship exists between selenium intake and cancer incidence, and selenium levels are usually lower in cancer patients.
*BioAv↑, favorable biocompatibility, good bioadhesivness, and low toxicity.
*toxicity↑,
TumCG↓, Studies have found that water-soluble chitosan can significantly inhibit the growth of liver cancer cells in a dose-dependent manner
AntiTum↑, SMC has been proved to possess stronger antitumor functions and lower toxicity in cancer patients
ROS↑, SMC induced A549 cell apoptosis via a reactive oxygen species–mediated mitochondrial apoptosis pathway, which upregulated Bax and downregulated Bcl2, promoted cytochrome C release from mitochondria to cytoplasm, and activated cleaved caspase 3
Cyt‑c↑,
Fas↑, upregulating the expression levels of Fas, FasL, and Fadd,
FasL↑,
FADD↑,

3289- SIL,    Silymarin: a promising modulator of apoptosis and survival signaling in cancer
- Review, Var, NA
*BioAv↝, silymarin’s poor bioavailability and limited thérapeutic efficacy have been overcome by encapsulation of silymarin into nanoparticles
*BioAv↓, Silymarin is barely 20–50% absorbed by the GIT cells and has an absolute oral bioavailability of 0.95%
Fas↑, silibinin, enhances the Fas pathway in most cancers cells by upregulating the Fas and Fas L
FasL↑,
FADD↑, silymarin triggered apoptosis via upregulating the expression of FADD (Fig. 2b), a downstream component of the death receptor pathway, subsequently leading to the cleavage of procaspase 8 and initiation of apoptotic cell death
pro‑Casp8↑,
Apoptosis↑,
DR5↑, silymarin promotes apoptosis through the death receptor-mediated pathway, contributing to its anticancer effects
Bcl-2↑, Bcl-2, an anti-apoptotic protein, was decreased
BAX↑, Bax is also upregulated and leads to the activation of caspase-3.
Casp3↑,
PI3K↓, Silibinin inhibits the PI3K activity, leading to the reduction of FoxM1 (Forkhead box M1) and the subsequent activation of the mitochondrial apoptotic pathway
FOXM1↓,
p‑mTOR↓, inhibiting phosphorylation of several key components in this pathway, such as mTOR, p70S6K and 4E-BP1
p‑P70S6K↓,
Hif1a↓, mTOR pathway signaling in turn may result in low levels of HIF-1α due to the unfavorable conditions of hypoxia.
Akt↑, silibinin activates the Akt pathway in cervical cancer cells. This activation of Akt could have some bearing on the overall antitumor activity of silibinin in cervical cancer cells.
angioG↓, silibinin inhibited STAT3, HIF-1α, and NF-κB, thereby reducing the population of lung macrophages and limiting angiogenesis
STAT3↓,
NF-kB↓,
lipid-P↓, silibinin delays the progression of endometrial carcinoma via inhibiting STAT3 activation and lowering lipid accumulation, which is regulated by SREBP1
eff↑, Sorafenib and silibinin work together to target both liver cancer cells and cancer stem cells. This combination operates by suppressing the STAT3/ERK/AKT pathways and decreasing the production of Mcl-1 and Bcl-2 proteins
CDK1↓, reducing the expression of CDK1, survivin, Bcl-xL, cyclinB1 and Mcl- 1 and simultaneously activate caspases 3 and 9
survivin↓,
CycB/CCNB1↓,
Mcl-1↓,
Casp9↑,
AP-1↓, hindered the activation of transcription factors NF-κB and AP-1
BioAv↑, Liang et al., created a chitosan-based lipid polymer hybrid nanoparticles that boosted the bioavailability of silymarin by 14.38-fold

1824- VitK2,    Vitamin K and its analogs: Potential avenues for prostate cancer management
- Review, Pca, NA
AntiCan↑, potential anticancer activity in several cancer types including prostate cancer
toxicity∅, VK1 and VK2 are non-toxic even at high doses
Risk↓, Epidemiological studies suggest that there is inverse association between dietary intake of VK (especially menaquinone) and overall cancer incidence
Apoptosis↑, VK2 has anticancer activity through the mechanisms such as induction of apoptosis, production of reactive oxygen species (ROS) and cell cycle arrest
ROS↑,
TumCCA↑,
eff↑, Gilloteaux et al. [90] reported that the combination of VK3 and ascorbic acid induces oxidative stress in DU-145 PCa cells.
DNAdam↑, oxidative stress induce lipid and protein oxidative modifications and DNA damage leading to apoptotic cell death
MMP↓, VK2 induces pro-apoptosis effects by regulating the MMP, in which mechanism VK2 produces superoxide within the mitochondrial membrane, followed by the release cytochrome c, activation of procaspase 3
Cyt‑c↑,
pro‑Casp3↑,
FasL↑, VK3 treatment induced c-myc and also increased both FasL and Fas
Fas↑,
TumAuto↑, VK2 also can induce autophagy
ChemoSen↑, combination of vitamins C and VK3 has been proposed as a non-toxic mixture of drugs active as an adjuvant cancer therapy by increasing chemo- or radiotherapy effects through alteration of deoxyribonuclease activity
RadioS↑,


Showing Research Papers: 1 to 18 of 18

* indicates research on normal cells as opposed to diseased cells
Total Research Paper Matches: 18

Pathway results for Effect on Cancer / Diseased Cells:


Redox & Oxidative Stress

Catalase↓, 1,   CYP1A1↓, 1,   GPx↓, 1,   GSH↓, 3,   GSH↑, 1,   GSH/GSSG↓, 1,   GSR↓, 1,   GSTs↓, 1,   HO-1↓, 1,   lipid-P↓, 1,   MDA↓, 1,   NQO1↓, 1,   NRF2↓, 2,   NRF2↑, 1,   ROS?, 1,   ROS↓, 1,   ROS↑, 12,   mt-ROS↑, 1,   SOD↓, 1,   SOD↑, 1,   SOD2↓, 1,   TrxR1↓, 1,   VitC↓, 1,   VitE↓, 1,  

Mitochondria & Bioenergetics

AIF↑, 1,   BOK↑, 1,   CDC25↓, 2,   EGF↓, 1,   ETC↓, 1,   FGFR1↓, 1,   MMP↓, 9,   Raf↓, 1,   XIAP↓, 2,  

Core Metabolism/Glycolysis

AMPK↑, 5,   cMyc↓, 1,   LDH↑, 1,   PDK1↓, 1,   PIK3CA↓, 1,   SIRT1↓, 2,  

Cell Death

Akt↓, 4,   Akt↑, 1,   p‑Akt↓, 2,   APAF1↑, 3,   Apoptosis↑, 12,   BAD↓, 1,   BAD↑, 2,   Bak↑, 1,   BAX↑, 12,   Bax:Bcl2↑, 1,   Bcl-2↓, 8,   Bcl-2↑, 1,   Bcl-xL↓, 1,   BID↑, 4,   Casp↑, 2,   Casp1↓, 1,   Casp3↓, 2,   Casp3↑, 12,   cl‑Casp3↑, 1,   pro‑Casp3↑, 1,   Casp7↑, 2,   Casp8↑, 9,   pro‑Casp8↑, 1,   Casp9↑, 11,   cl‑Casp9↑, 1,   cFLIP↓, 3,   Cyt‑c↑, 11,   DR4↑, 1,   DR4∅, 1,   DR5↑, 7,   FADD↑, 8,   Fas↓, 1,   Fas↑, 10,   FasL↑, 19,   HGF/c-Met↓, 1,   IAP1↓, 2,   IAP2↓, 1,   JNK↑, 3,   p‑JNK↑, 1,   MAPK↓, 5,   MAPK↑, 3,   Mcl-1↓, 2,   MDM2↓, 2,   p‑MDM2↓, 1,   MKP1↓, 1,   MKP2↓, 1,   NAIP↓, 1,   p27↑, 1,   p38↑, 1,   p‑p38↑, 2,   survivin↓, 3,   TRAIL↑, 2,   TUNEL↑, 1,  

Kinase & Signal Transduction

HER2/EBBR2↓, 1,  

Transcription & Epigenetics

H3↓, 1,   H4↓, 1,   miR-21↑, 1,   other↓, 1,   p‑pRB↓, 1,   tumCV↓, 4,   tumCV↑, 1,  

Protein Folding & ER Stress

CHOP↑, 2,   p‑eIF2α↑, 1,   GRP78/BiP↑, 1,   HSP70/HSPA5↓, 1,   HSP90↓, 2,  

Autophagy & Lysosomes

Beclin-1↑, 1,   BNIP3↝, 1,   LC3B-II↑, 1,   LC3II↑, 2,   TumAuto↑, 4,  

DNA Damage & Repair

ATM↑, 1,   DNAdam↑, 4,   P53↑, 6,   PARP↓, 1,   PARP↑, 2,   cl‑PARP↑, 3,   PCNA↓, 1,  

Cell Cycle & Senescence

CDK1↓, 2,   CDK2↑, 1,   CDK4↓, 1,   CycB/CCNB1↓, 4,   cycD1/CCND1↓, 1,   cycE1↓, 1,   P21↑, 2,   RB1↑, 1,   TumCCA↑, 11,  

Proliferation, Differentiation & Cell State

CD34↓, 1,   cFos↓, 1,   cFos↑, 1,   CSCs↓, 1,   EMT↓, 2,   EMT↑, 1,   ERK↓, 2,   ERK↑, 2,   FGF↓, 1,   FOXM1↓, 1,   Gli1↓, 1,   GSK‐3β↑, 1,   HDAC↓, 1,   IGFBP3↑, 1,   mTOR↓, 6,   p‑mTOR↓, 1,   NOTCH↓, 2,   NOTCH1↓, 1,   p‑P70S6K↓, 1,   PI3K↓, 3,   p‑PI3K↓, 1,   PTEN↓, 1,   RAS↓, 2,   Shh↓, 1,   Smo↓, 1,   p‑Src↓, 1,   STAT3↓, 3,   p‑STAT6↓, 1,   TRPM7↓, 1,   TumCG↓, 3,   Wnt↓, 1,   Wnt/(β-catenin)↓, 1,  

Migration

AP-1↓, 1,   AXL↓, 1,   Cdc42↓, 1,   CEA↓, 1,   CLDN1↓, 1,   E-cadherin↓, 1,   FAK↓, 3,   ITGB1↓, 1,   MET↓, 1,   p‑MET↓, 1,   MMP1↓, 1,   MMP13↓, 1,   MMP2↓, 4,   MMP3↓, 1,   MMP9↓, 3,   MMPs↓, 2,   N-cadherin↓, 1,   PDGF↓, 1,   Rac1↓, 1,   Rho↓, 2,   ROCK1↓, 1,   Snail↓, 1,   TGF-β↓, 2,   TSP-1↑, 1,   TumCI↓, 2,   TumCP↓, 2,   TumMeta↓, 2,   Tyro3↓, 1,   uPA↓, 2,   uPAR↓, 1,   Vim↑, 1,   ZO-1↑, 1,   β-catenin/ZEB1↓, 1,  

Angiogenesis & Vasculature

angioG↓, 5,   EGFR↓, 3,   EGFR↑, 1,   Hif1a↓, 3,   VEGF↓, 4,   VEGFR2↓, 1,  

Barriers & Transport

P-gp↓, 1,  

Immune & Inflammatory Signaling

ASC↓, 1,   CD4+↓, 1,   COX2↓, 3,   CRP↓, 1,   ICAM-1↓, 1,   IKKα↓, 1,   IL1↓, 1,   IL10↓, 1,   IL1β↓, 1,   IL2↑, 1,   IL6↓, 3,   Inflam↓, 1,   MCP1↓, 1,   NF-kB↓, 7,   p‑p65↓, 1,   PD-1↓, 1,   PGE2↓, 1,   TLR4↓, 1,   TNF-α↓, 2,   TNF-α↑, 1,  

Protein Aggregation

NLRP3↓, 1,  

Hormonal & Nuclear Receptors

AR↓, 1,  

Drug Metabolism & Resistance

BioAv↓, 3,   BioAv↑, 3,   BioAv↝, 1,   ChemoSen↑, 5,   Dose↝, 1,   eff↓, 4,   eff↑, 7,   eff↝, 1,   RadioS↑, 4,   selectivity↑, 1,   selectivity∅, 1,  

Clinical Biomarkers

AR↓, 1,   CEA↓, 1,   CRP↓, 1,   EGFR↓, 3,   EGFR↑, 1,   FOXM1↓, 1,   HER2/EBBR2↓, 1,   IL6↓, 3,   LDH↑, 1,   NSE↓, 1,  

Functional Outcomes

AntiCan↑, 4,   AntiTum↑, 2,   cachexia↓, 1,   chemoP↑, 1,   RenoP↑, 1,   Risk↓, 2,   toxicity∅, 1,  
Total Targets: 248

Pathway results for Effect on Normal Cells:


Redox & Oxidative Stress

antiOx↑, 1,   Catalase↑, 2,   GPx↑, 2,   GSH↑, 1,   GSTs↑, 1,   lipid-P↓, 1,   ROS↓, 2,   ROS↑, 2,   SOD↑, 1,  

Mitochondria & Bioenergetics

MMP↑, 1,  

Cell Death

Akt↓, 1,   Casp3↓, 2,   Casp9↓, 1,   Cyt‑c↓, 1,   MAPK↓, 1,  

Transcription & Epigenetics

other↑, 2,   other↝, 2,  

Protein Folding & ER Stress

HSP70/HSPA5↑, 1,   HSPs↑, 1,  

Proliferation, Differentiation & Cell State

PI3K↓, 1,  

Migration

MMP9↓, 1,  

Immune & Inflammatory Signaling

COX1↓, 1,   COX2↓, 1,   CRP↓, 1,   CXCR4↓, 1,   IL10↑, 1,   IL17↓, 1,   IL18↓, 1,   IL1β↓, 2,   IL6↓, 1,   Inflam↓, 1,   PGE2↓, 1,   TNF-α↓, 2,  

Drug Metabolism & Resistance

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

Clinical Biomarkers

CRP↓, 1,   IL6↓, 1,  

Functional Outcomes

cardioP↑, 1,   hepatoP↑, 1,   neuroP↑, 2,   toxicity↑, 1,  
Total Targets: 46

Scientific Paper Hit Count for: FasL, Fas ligand
3 Baicalein
2 Berberine
2 chitosan
2 Selenium
1 Carvacrol
1 Thymol-Thymus vulgaris
1 Celastrol
1 Selenate
1 Chrysin
1 Date Fruit Extract
1 Gambogic Acid
1 Luteolin
1 Propyl gallate
1 Plumbagin
1 Quercetin
1 Silymarin (Milk Thistle) silibinin
1 Vitamin K2
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#:593  State#:%  Dir#:2
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