SOD2 Cancer Research Results

SOD2, MnSOD: Click to Expand ⟱
Source:
Type: protein
Manganese superoxide dismutase (MnSOD, also known as SOD2).
SOD2 (Superoxide Dismutase 2) is a protein that is a member of the superoxide dismutase family of enzymes, which are involved in the detoxification of superoxide radicals.

-MnSOD is localized in the mitochondria and plays a key role in detoxifying superoxide radicals, thereby limiting oxidative damage and maintaining mitochondrial integrity.
• By modulating ROS levels, MnSOD influences cellular signaling pathways involved in proliferation, apoptosis, and metabolic adaptation—all of which are critical during tumorigenesis.

Typically low SOD2 expression in cancers, with poor prognosis.

-Increased MnSOD levels may help tumor cells manage the high levels of ROS resulting from rapid cell division and metabolic alterations, which can contribute to tumor progression.
- Some prognostic studies associate high levels of MnSOD with resistance to apoptosis and poorer patient outcomes; however, findings are not entirely consistent across all studies.

• Depending on the tumor type and the balance with other antioxidant systems, high MnSOD can be associated with either favorable or unfavorable clinical outcomes, reflecting its dual roles in cancer biology.
Scientific Papers found: Click to Expand⟱
2612- Ba,  MF,    The effect of a static magnetic field and baicalin or baicalein interactions on amelanotic melanoma cell cultures (C32)
- in-vitro, Melanoma, NA
SOD1↑, Baicalein ONLY: increase in the expression of the SOD1 , SOD2 and GPX1 genes compared to the nontreated cell cultures
SOD2↑,
GPx1↑,
Dose?, A chamber with a field induction of 0.7 T was used for the tests
eff↝, There was no significant difference in the expression of the SOD1, SOD2 or GPX1 genes in the melanoma cell cultures that had only been exposed to a static magnetic field (0.7 T)
SOD1↓, Baicalein + 0.7T MF: decreases SOD1 , SOD2 and GPX1
SOD2↓,
GPx1↓,

5536- BBM,    Regulation of Cell-Signaling Pathways by Berbamine in Different Cancers
- Review, Var, NA
JAK↝, In this review, we comprehensively analyze how berbamine modulates deregulated pathways (JAK/STAT, CAMKII/c-Myc) in various cancers.
STAT3↓, Berbamine physically interacted with STAT3 and inhibited its activation [8].
p‑CaMKII ↓, An orally administered, bioactive small molecule analog of berbamine, tosyl chloride-berbamine (TCB), considerably reduced phosphorylated levels of CaMKIIγ
TGF-β↑, berbamine induces activation of the TGF/SMAD pathway for the effective inhibition of cancer progression.
Smad1↑,
ChemoSen↑, Berbamine enhanced the chemosensitivity of gefitinib against PANC-1 and MIA PaCa-2 cancer cells [8].
RadioS↑, Moreover, berbamine and radiation effectively induced a regression of the tumors in mice subcutaneously injected with FaDu cells [10].
TumCI↓, berbamine-GMO-TPGS nanoparticles showed superior cellular toxicity, as well as an inhibition of migration and invasion in metastatic breast cancer MDA-MB-231,
TumCMig↓,
ROS↑, Berbamine increased the intracellular ROS levels via the downregulation of antioxidative genes such as NRF2, SOD2, GPX-1 and HO-1.
NRF2↓,
SOD2↓,
GPx1↓,
HO-1↓,

5551- BBM,    Berbamine Suppresses the Progression of Bladder Cancer by Modulating the ROS/NF-κB Axis
- vitro+vivo, Bladder, NA
tumCV↓, our results showed that berbamine inhibited cell viability, colony formation, and proliferation.
TumCP↓,
TumCCA↑, Additionally, berbamine induced cell cycle arrest at S phase by a synergistic mechanism involving stimulation of P21 and P27 protein expression
P21↑,
p27↑,
cycD1/CCND1↓, as well as downregulation of CyclinD, CyclinA2, and CDK2 protein expression.
cycA1/CCNA1↓,
CDK2↓,
EMT↓, In addition to suppressing epithelial-mesenchymal transition (EMT), berbamine rearranged the cytoskeleton to inhibit cell metastasis.
TumMeta↓,
p65↓, Mechanistically, the expression of P65, P-P65, and P-IκBα was decreased upon berbamine treatment
p‑p65↓,
IKKα↓,
NF-kB↑, berbamine attenuated the malignant biological activities of BCa cells by inhibiting the NF-κB pathway.
ROS↑, More importantly, berbamine increased the intracellular reactive oxygen species (ROS) level through the downregulation of antioxidative genes such as Nrf2, HO-1, SOD2, and GPX-1.
NRF2↓,
HO-1↓,
SOD2↓,
GPx1↓,
Bax:Bcl2↑, increase in the ratio of Bax/Bcl-2.
TumVol↓, berbamine successfully inhibited tumor growth and blocked the NF-κB pathway in our xenograft model

2717- BetA,    Betulinic Acid Induces ROS-Dependent Apoptosis and S-Phase Arrest by Inhibiting the NF-κB Pathway in Human Multiple Myeloma
- in-vitro, Melanoma, U266 - in-vivo, Melanoma, NA - in-vitro, Melanoma, RPMI-8226
Apoptosis↑, BA mediated cytotoxicity in MM cells through apoptosis, S-phase arrest, mitochondrial membrane potential (MMP) collapse, and overwhelming reactive oxygen species (ROS) accumulation.
TumCCA↑, S-Phase Arrest in U266 Cells
MMP↓,
ROS↑, exhibited concentration-dependent increases in intracellular ROS
eff↓, ROS scavenger N-acetyl cysteine (NAC) effectively abated elevated ROS, the BA-induced apoptosis was partially reversed
NF-kB↓, BA resulted in marked inhibition of the aberrantly activated NF-κB pathway in MM
Cyt‑c↑, BA mediated the release of cyt c and activated cleaved caspase-3, caspase-8, and caspase-9 and cleaved PARP1
Casp3↑,
Casp8↑,
Casp9↑,
cl‑PARP1↑,
MDA↑, here is a concentration-dependent increase in MDA contents and reduction in SOD activities, especially for the high concentration group.
SOD↓,
SOD2↓, expression of genes SOD2, FHC, GCLM, and GSTM was all decreased following treatment with BA (40 μM)
GCLM↓,
GSTA1↓,
FTH1↓, FHC
GSTs↓, GSTM
TumVol↓, BA Inhibits the Growth of MM Xenograft Tumors In Vivo. BA-treated group were significantly reduced (inhibition ratio of approximately 72.1%).

2736- BetA,  Chemo,    Multifunctional Roles of Betulinic Acid in Cancer Chemoprevention: Spotlight on JAK/STAT, VEGF, EGF/EGFR, TRAIL/TRAIL-R, AKT/mTOR and Non-Coding RNAs in the Inhibition of Carcinogenesis and Metastasis
- Review, Var, NA
chemoPv↑, reviews about cancer chemopreventive role of betulinic acid against wide variety of cancers [18,19,20,21].
p‑STAT3↓, betulinic acid reduced the levels of p-STAT3 in tumor tissues derived from KB cells
JAK1↓, Betulinic acid exerted inhibitory effects on the constitutive phosphorylation of JAK1 and JAK2
JAK2↓,
VEGF↓, betulinic acid mediated inhibition of VEGF
EGFR↓, evaluation of betulinic acid as a next-generation EGFR inhibitor
Cyt‑c↑, release of SMAC/DIABLO and cytochrome c from mitochondria in SHEP neuroblastoma cells
Diablo↑,
AMPK↑, Betulinic acid induced activation of AMPK and consequently reduced the activation of mTOR.
mTOR↓,
Sp1/3/4↓, Betulinic acid significantly reduced the quantities of Sp1, Sp3 and Sp4 in the tissues of the tumors derived from RKO cells
DNAdam↑, Betulinic acid efficiently triggered DNA damage (γH2AX) and apoptosis (caspase-3 and p53 phosphorylation) in temozolomide-sensitive and temozolomide-resistant glioblastoma cells.
Gli1↓, Betulinic acid effectively reduced GLI1, GLI2 and PTCH1 in RMS-13 cells.
GLI2↓,
PTCH1↓,
MMP2↓, betulinic acid exerted inhibitory effects on MMP-2 and MMP-9 in HepG2 cells.
MMP9↓,
miR-21↓, Collectively, p53 increased miR-21 levels and inhibited SOD2 levels, leading to significant increase in the accumulation of ROS levels and apoptotic cell death.
SOD2↓,
ROS↑,
Apoptosis↑,

5689- BJ,    Brucea javanica oil inhibited the proliferation, migration, and invasion of oral squamous carcinoma by regulated the MTFR2 pathway
- vitro+vivo, Oral, CAL27
TumCP↓, BJO treatment significantly inhibited the proliferation, migration, and invasiveness of OSCC cells
TumCMig↓,
TumCI↓,
SOD2↓, BJO could effectively reduce the expression levels of MTFR2 and SOD2/H2O2 related signal transduction pathways.
H2O2↓,
OXPHOS↑, At the same time, the expression of oxidative phosphorylation markers increased, the expression of glycolytic markers decreased
Glycolysis↓, down-regulation of MTFR2-mediated aerobic glycolysis
ROS↑, Wang D et al. suggested that Brucea javanica oil induces cell cycle arrest and apoptosis in lung cancer cells through reactive oxygen species (ROS)-mediated mitochondrial dysfunction (14).
RadioS↑, Pan P et al. reported that Brucea javanica oil enhances the radio-sensitization of esophageal cancer cells by inhibiting HIF1α (15).
Hif1a↓,
TumCG↓, BJO represses the xenograft tumor growth in vivo

2899- HNK,    SIRT3 activator honokiol ameliorates surgery/anesthesia-induced cognitive decline in mice through anti-oxidative stress and anti-inflammatory in hippocampus
- in-vivo, Nor, NA
*memory↑, Honokiol attenuated surgery-induced memory loss and neuronal apoptosis, decreased neuroinflammatory response, and ameliorated oxidative damage in hippocampus.
*Inflam↓,
*ROS↓,
neuroP↑,
SIRT3↑, HNK increased SIRT3 expression and thus decreased the acetylation of superoxide dismutase 2 (SOD2).
ac‑SOD2↓,

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

2255- MF,    Pulsed Electromagnetic Fields Induce Skeletal Muscle Cell Repair by Sustaining the Expression of Proteins Involved in the Response to Cellular Damage and Oxidative Stress
- in-vitro, Nor, SkMC
*HSP70/HSPA5↑, HSP70), which can promote muscle recovery, inhibits apoptosis and decreases inflammation in skeletal muscle, together with thioredoxin, paraoxonase, and superoxide dismutase (SOD2), which can also promote skeletal muscle regeneration following injury
*Apoptosis↓,
*Inflam↓,
*Trx↓,
*PONs↓, Paraoxonase 2 (PON2, Paraoxonase 3 (PON3) (+19% vs. controls)
*SOD2↓,
*TumCG↑, PEMF treatment enhanced muscle cell proliferation by approximately 20% both in cells grown in complete medium
*Diff↑, suggest the potential role of PEMF in the induction of muscle differentiation
*HIF2a↑, hypoxia-inducible transcription factor 2a (HIF-2a) (+40% vs. controls),
*Cyt‑c↑, Cytochrome c (+39% vs. controls)
P21↑, p21/CIP1 (+27% vs. controls)

4643- OLE,  HT,    Use of Oleuropein and Hydroxytyrosol for Cancer Prevention and Treatment: Considerations about How Bioavailability and Metabolism Impact Their Adoption in Clinical Routine
- Review, Var, NA
TumCCA↑, A similar S phase cell cycle arrest was also observed for 800 μM HT, and induction of apoptosis also took place after 24 h incubation of HT-29 cells with 600 μM and 800 μM HT
Apoptosis↑,
ER Stress↑, 400 μM HT triggered endoplasmic reticulum stress in HT-29 cells, with activation of unfolded protein response,
UPR↑,
CHOP↑, increase in CHOP protein levels (responsible for ROS production and Bcl-2 downregulation) and NADPH oxidase 4 (NOX4)
ROS↑,
Bcl-2↓,
NOX4↑,
Hif1a↓, Moreover, 400 μM HT reduced HIF-1α protein levels
MMP2↓, figure 2
MMP↓,
VEGF↓,
Akt↓,
NF-kB↓,
p65↓,
SIRT3↓,
mTOR↓,
Catalase↓,
SOD2↓,
FASN↓,
STAT3↓,
HDAC2↓,
HDAC3↓,
BAD↑, figure 2 upregulated
BAX↑,
Bak↑,
Casp3↑,
Casp9↑,
PARP↑,
P53↑,
P21↑,
p27↑,
Half-Life↝, HT added to extra virgin olive oil produced a plasma peak of 3.79 ng/mL after 30 min, followed by a rapid decline in HT plasma concentration
BioAv↓, On the basis of these pieces of data, it becomes evident that cytotoxicity and anti-cancer effects of OLE and HT were recorded at concentrations largely exceeding those reachable with diet/olive oil consumption
BioAv↓, Thus, it is difficult to imagine how OLE and HT may be used as cancer-preventive/treating agents if the route of administration is ingestion.
selectivity↑, However, even at high concentrations, OLE and HT seem to be selectively cytotoxic for cancer cells, with no or negligible/minimal effects on non-cancer cells,
RadioS↑, 200 μM OLE enhanced cell radiosensitivity in vitro and in vivo after injection in BALB/C nude mice
*ROS↓, A lot of experimental data in vivo and in vitro have definitively demonstrated the ROS scavenger ability of OLE and HT, which can also act on antioxidant cellular mechanisms restoring ROS homeostasis,
*GSH↑, including promotion of the increase in reduced glutathione levels (GSH), depletion of lipid peroxidation product malondialdehyde (MDA), intensification of the expression and/or activity of detoxicating enzymes SOD, CAT, glutathione-S-transferase (GST
*MDA↓,
*SOD↑,
*Catalase↑,
*NRF2↑, and nuclear factor E2-related factor 2 (Nrf2) upregulation/transactivation,
*chemoP↑, OLE and HT have shown an important ability to mitigate the toxicity elicited by chemotherapeutic agents mainly through their largely demonstrated antioxidant and ROS scavenger activity.
*Inflam↓, OLE and HT exhibit an anti-inflammatory activity that has been demonstrated in multiple in vivo and in vitro models,
PPARγ↑, HT-dependent anti-inflammatory effect was also mediated by HT-elicited increase in protein levels of PPARγ

1987- PTL,  Rad,    A NADPH oxidase dependent redox signaling pathway mediates the selective radiosensitization effect of parthenolide in prostate cancer cells
- in-vitro, Pca, PC3 - in-vitro, Nor, PrEC
selectivity↑, parthenolide (PN), a sesquiterpene lactone, selectively exhibits a radiosensitization effect on prostate cancer PC3 cells but not on normal prostate epithelial PrEC cells.
RadioS↑,
ROS↑, oxidative stress in PC3 cells but not in PrEC cells
*ROS∅, oxidative stress in PC3 cells but not in PrEC cells
NADPH↑, In PC3 but not PrEC cells, PN activates NADPH oxidase leading to a decrease in the level of reduced thioredoxin, activation of PI3K/Akt and consequent FOXO3a phosphorylation, which results in the downregulation of FOXO3a targets, MnSOD, CAT
Trx↓,
PI3K↑,
Akt↑,
p‑FOXO3↓, downregulation of FOXO3a targets, antioxidant enzyme manganese superoxide dismutase (MnSOD) and catalase
SOD2↓, MnSOD
Catalase↓,
radioP↑, when combined with radiation, PN further increases ROS levels in PC3 cells, while it decreases radiation-induced oxidative stress in PrEC cells
*NADPH∅, Parthenolide activates NADPH oxidase in PC3 cells but not in PrEC cells
*GSH↑, increases glutathione (GSH) in PrEC cells(normal cells)
*GSH/GSSG↑, GSH/GSSG ratio is not significantly changed by parthenolide in PC3 cells but is increased 2.4 fold in PrEC cells (normal cells)
*NRF2↑, The induction of GSH may be due to the activation of the Nrf2/ARE (antioxidant/electrophile response element) pathway

3929- PTS,    New Insights into Dietary Pterostilbene: Sources, Metabolism, and Health Promotion Effects
- Review, Var, NA - Review, Arthritis, NA
*NRF2↑, PTS activates the Nrf2 pathway,
*BioAv↑, , PTS has been documented to exhibit an increased bioavailability compared to other stilbene compounds
*ROS↓, Various evidence has demonstrated the effect of PTS in countering oxidative damage and inflammation, imparting preventive and therapeutic benefits in experimental disease models
*Inflam↓,
*HO-1↑, major downstream targets activated following PTS administration were antioxidative enzymes, including HO 1, SOD, catalase, and GPX
*SOD↑,
*Catalase↑,
*GPx↑,
*lipid-P↓, reducing lipid peroxidation in STZ-induced diabetic mice.
*hepatoP↑, figure 4
*neuroP↑,
*iNOS↓, PTS inhibited the transcriptional expression of augmented iNOS levels and moderated the inhibition of COX-2 in a concentration-dependent manner
*COX2↓,
TumMeta↓, PTS in combination with quercetin at 20 mg/kg/day inhibited the metastatic activity in B16-F10 melanoma by reducing the adhesion of B16-F10 cells to the endothelium and also downregulated the levels of Bcl-2 in cancerous cells
SOD2↓, PTS was identified to reduce HCC proliferation through a reduction in SOD2 and the induction of ROS-mediated mitochondrial apoptotic pathways
ROS↑,
TumCI↓, PTS was reported to suppress the invasion and growth of HCC by down-regulating the expression of Metastasis-Associated Protein 1 (MTA1) and histone deacetylase 1 (HDAC1) while upregulating the acetylation of the tumor suppressor protein PTEN
TumCG↓,
HDAC1↓,
PTEN↑,
BP↓, highly purified trans-PTS patented by Chromadex, Irvine, CA, has been proven to significantly reduce blood pressure in adults
*GutMicro↑, PTS significantly reduced paw swelling, the arthritic score, and body weight. Interestingly, it also helped restore the healthy gut microbiota ecosystem by reducing the relative abundance of Helicobacter, Desulfovibrio, Lachnospiraceae, and Mucispiri

3068- RES,    Resveratrol decreases the expression of genes involved in inflammation through transcriptional regulation
- in-vitro, lymphoma, U937
p65↓, In our study, RESV treatment significantly decreased p65 expression and reduced the activities of the antioxidant enzymes SOD2, PRX2, CAT, and TRX.
SOD2↓,
Prx↓,
Catalase↓,
Trx↓,
TNF-α↓, (i.e., TNF-α, IL-8, and MCP-1), whereas a reduction in the protein levels of these cytokines was observed in the presence of RESV.
IL8↓,
MCP1↓,
SIRT1↑, a trend of increased SIRT1 activity in the presence of RESV was observed, which may be due to the low dose of RESV used

3017- RosA,  Per,    Molecular Mechanism of Antioxidant and Anti-Inflammatory Effects of Omega-3 Fatty Acids in Perilla Seed Oil and Rosmarinic Acid Rich Fraction Extracted from Perilla Seed Meal on TNF-α Induced A549 Lung Adenocarcinoma Cells
- in-vitro, Lung, A549
TumCD∅, We found that PSO and RA-RF were not toxic to TNF-α-induced A549 cells.
ROS↓, Both extracts significantly decreased the generation of reactive oxygen species (ROS) in this cell line.
IL1β↓, mRNA expression levels of IL-1β, IL-6, IL-8, TNF-α, and COX-2 were significantly decreased by the treatment of PSO and RA-RF.
IL6↓,
IL8↓,
TNF-α↓,
COX2↓,
SOD2↓, MnSOD, FOXO1, and NF-κB and phosphorylation of JNK were also significantly diminished by PSO and RA-RF treatment
FOXO1↓,
NF-kB↓,
JNK↓,
antiOx↑, PSO and RA-RF act as antioxidants
tumCV∅, PSO and RA-RF had no effect on A549 cell viability.

4730- Se,    Association between plasma selenium level and NRF2 target genes expression in humans
- Human, Nor, NA
*NRF2↑, NRF2 mRNA level was positively correlated with expression of investigated NRF2-target genes.
*GSTP1/GSTπ↓, plasma Se level was significantly inversely associated only with expression of GSTP1 (β-coef. = −0.270, p = 0.009), PRDXR1 (β-coef. = −0.245, p = 0.017) and SOD2 with an inverse trend toward significance
*SOD2↓,

3296- SIL,    Silibinin induces oral cancer cell apoptosis and reactive oxygen species generation by activating the JNK/c-Jun pathway
- in-vitro, Oral, Ca9-22 - in-vivo, Oral, YD10B
TumCP↓, Silibinin effectively suppressed YD10B and Ca9-22 cell proliferation and colony formation in a dose-dependent manner.
TumCCA↑, Moreover, it induced cell cycle arrest in the G0/G1 phase, apoptosis, and ROS generation in these cells.
ROS↑,
SOD1↓, silibinin downregulated SOD1 and SOD2 and triggered the JNK/c-Jun pathway in oral cancer cells.
SOD2↓,
*JNK↑, inducing apoptosis, G0/G1 arrest, ROS generation, and activation of the JNK/c-Jun pathway.
toxicity?, Silibinin significantly inhibited xenograft tumor growth in nude mice, with no obvious toxicity.
TumCMig↓, Silibinin inhibits oral cancer cell migration and invasion
TumCI↓,
N-cadherin↓, silibinin downregulated N-cadherin and vimentin expression and upregulated E-cadherin expression in YD10B and Ca9-22 cells
Vim↓,
E-cadherin↑,
EMT↓, Together, these results indicate that silibinin inhibits the migration and invasion of oral cancer cells by suppressing the EMT.
P53↑, silibinin significantly induced the expression of p53, cleaved caspase-3, cleaved PARP, and Bax, and downregulated the expression of the anti-apoptotic marker protein Bcl-2
cl‑Casp3↑,
cl‑PARP↑,
BAX↑,
Bcl-2↓,
SOD↓, silibinin inhibits SOD expression, induces ROS production, and activates the JNK/c-Jun pathway in oral cancer cells.


Showing Research Papers: 1 to 16 of 16

* indicates research on normal cells as opposed to diseased cells
Total Research Paper Matches: 16

Pathway results for Effect on Cancer / Diseased Cells:


Redox & Oxidative Stress

antiOx↑, 1,   Catalase↓, 4,   CYP1A1↓, 1,   GCLM↓, 1,   GPx↓, 1,   GPx1↓, 3,   GPx1↑, 1,   GSH↓, 2,   GSR↓, 1,   GSTA1↓, 1,   GSTs↓, 2,   H2O2↓, 1,   HO-1↓, 3,   MDA↑, 1,   NOX4↑, 1,   NQO1↓, 1,   NRF2↓, 3,   OXPHOS↑, 1,   Prx↓, 1,   ROS↓, 1,   ROS↑, 10,   SIRT3↓, 1,   SIRT3↑, 1,   SOD↓, 3,   SOD1↓, 2,   SOD1↑, 1,   SOD2↓, 13,   SOD2↑, 1,   ac‑SOD2↓, 1,   Trx↓, 2,   VitC↓, 1,   VitE↓, 1,  

Metal & Cofactor Biology

FTH1↓, 1,  

Mitochondria & Bioenergetics

AIF↑, 1,   MMP↓, 2,   XIAP↓, 1,  

Core Metabolism/Glycolysis

AMPK↑, 1,   FASN↓, 1,   Glycolysis↓, 1,   NADPH↑, 1,   PPARγ↑, 1,   SIRT1↓, 1,   SIRT1↑, 1,  

Cell Death

Akt↓, 1,   Akt↑, 1,   p‑Akt↓, 1,   Apoptosis↑, 3,   BAD↑, 1,   Bak↑, 1,   BAX↑, 2,   Bax:Bcl2↑, 1,   Bcl-2↓, 3,   Casp1↓, 1,   Casp3↑, 3,   cl‑Casp3↑, 1,   Casp8↑, 2,   Casp9↑, 2,   Cyt‑c↑, 3,   Diablo↑, 1,   DR5↑, 1,   Fas↑, 1,   FasL↑, 1,   HGF/c-Met↓, 1,   JNK↓, 1,   p‑JNK↑, 1,   MAPK↓, 1,   p‑MDM2↓, 1,   p27↑, 2,   p‑p38↑, 1,   TumCD∅, 1,  

Kinase & Signal Transduction

p‑CaMKII ↓, 1,   Sp1/3/4↓, 1,  

Transcription & Epigenetics

H3↓, 1,   H4↓, 1,   miR-21↓, 1,   tumCV↓, 1,   tumCV∅, 1,  

Protein Folding & ER Stress

CHOP↑, 2,   p‑eIF2α↑, 1,   ER Stress↑, 1,   UPR↑, 1,  

Autophagy & Lysosomes

LC3II↑, 1,  

DNA Damage & Repair

DNAdam↑, 1,   P53↑, 2,   PARP↑, 2,   cl‑PARP↑, 1,   cl‑PARP1↑, 1,   PCNA↓, 1,  

Cell Cycle & Senescence

CDK2↓, 1,   cycA1/CCNA1↓, 1,   cycD1/CCND1↓, 1,   P21↑, 3,   TumCCA↑, 4,  

Proliferation, Differentiation & Cell State

CD34↓, 1,   cFos↑, 1,   EMT↓, 3,   FOXO1↓, 1,   p‑FOXO3↓, 1,   Gli1↓, 1,   HDAC↓, 1,   HDAC1↓, 1,   HDAC2↓, 1,   HDAC3↓, 1,   mTOR↓, 3,   NOTCH1↓, 1,   PI3K↑, 1,   p‑PI3K↓, 1,   PTCH1↓, 1,   PTEN↓, 1,   PTEN↑, 1,   p‑Src↓, 1,   STAT3↓, 3,   p‑STAT3↓, 1,   p‑STAT6↓, 1,   TumCG↓, 2,  

Migration

AXL↓, 1,   Cdc42↓, 1,   CEA↓, 1,   CLDN1↓, 1,   E-cadherin↓, 1,   E-cadherin↑, 1,   FAK↓, 1,   GLI2↓, 1,   ITGB1↓, 1,   MET↓, 1,   p‑MET↓, 1,   MMP2↓, 3,   MMP9↓, 1,   N-cadherin↓, 2,   Rac1↓, 1,   Rho↓, 1,   Smad1↑, 1,   Snail↓, 1,   TGF-β↑, 1,   TumCI↓, 4,   TumCMig↓, 3,   TumCP↓, 3,   TumMeta↓, 2,   Tyro3↓, 1,   Vim↓, 1,   Vim↑, 1,   ZO-1↑, 1,   β-catenin/ZEB1↓, 1,  

Angiogenesis & Vasculature

EGFR↓, 1,   EGFR↑, 1,   Hif1a↓, 2,   VEGF↓, 3,  

Immune & Inflammatory Signaling

ASC↓, 1,   COX2↓, 1,   ICAM-1↓, 1,   IKKα↓, 2,   IL1β↓, 1,   IL2↑, 1,   IL6↓, 2,   IL8↓, 2,   JAK↝, 1,   JAK1↓, 1,   JAK2↓, 1,   MCP1↓, 1,   NF-kB↓, 4,   NF-kB↑, 1,   p65↓, 3,   p‑p65↓, 2,   PD-1↓, 1,   TNF-α↓, 2,  

Protein Aggregation

NLRP3↓, 1,  

Hormonal & Nuclear Receptors

AR↓, 1,  

Drug Metabolism & Resistance

BioAv↓, 2,   BioAv↑, 1,   ChemoSen↑, 2,   Dose?, 1,   eff↓, 1,   eff↝, 1,   Half-Life↝, 1,   RadioS↑, 5,   selectivity↑, 2,  

Clinical Biomarkers

AR↓, 1,   BP↓, 1,   CEA↓, 1,   EGFR↓, 1,   EGFR↑, 1,   IL6↓, 2,   NSE↓, 1,  

Functional Outcomes

cachexia↓, 1,   chemoP↑, 1,   chemoPv↑, 1,   neuroP↑, 1,   radioP↑, 1,   toxicity?, 1,   TumVol↓, 2,  
Total Targets: 190

Pathway results for Effect on Normal Cells:


Redox & Oxidative Stress

Catalase↑, 3,   GPx↑, 2,   GSH↑, 3,   GSH/GSSG↑, 1,   GSTP1/GSTπ↓, 1,   GSTs↑, 1,   HO-1↑, 1,   lipid-P↓, 2,   MDA↓, 1,   NRF2↑, 4,   ROS↓, 3,   ROS∅, 1,   SOD↑, 3,   SOD2↓, 2,   Trx↓, 1,  

Core Metabolism/Glycolysis

NADPH∅, 1,   PONs↓, 1,  

Cell Death

Apoptosis↓, 1,   Casp3↓, 1,   Cyt‑c↑, 1,   iNOS↓, 1,   JNK↑, 1,  

Protein Folding & ER Stress

HSP70/HSPA5↑, 1,  

Proliferation, Differentiation & Cell State

Diff↑, 1,   TumCG↑, 1,  

Angiogenesis & Vasculature

HIF2a↑, 1,  

Immune & Inflammatory Signaling

COX2↓, 1,   IL10↑, 1,   IL1β↓, 1,   Inflam↓, 4,   TNF-α↓, 1,  

Drug Metabolism & Resistance

BioAv↑, 1,   eff↑, 1,   Half-Life↝, 1,  

Clinical Biomarkers

GutMicro↑, 1,  

Functional Outcomes

chemoP↑, 1,   hepatoP↑, 1,   memory↑, 1,   neuroP↑, 1,  
Total Targets: 39

Scientific Paper Hit Count for: SOD2, MnSOD
2 Magnetic Fields
2 Berbamine
2 Betulinic acid
1 Baicalein
1 Chemotherapy
1 Brucea javanica
1 Honokiol
1 Luteolin
1 Oleuropein
1 HydroxyTyrosol
1 Parthenolide
1 Radiotherapy/Radiation
1 Pterostilbene
1 Resveratrol
1 Rosmarinic acid
1 Perilla
1 Selenium
1 Silymarin (Milk Thistle) silibinin
Query results interpretion may depend on "conditions" listed in the research papers.
Such Conditions may include : 
  -low or high Dose
  -format for product, such as nano of lipid formations
  -different cell line effects
  -synergies with other products 
  -if effect was for normal or cancerous cells

Filter Conditions: Pro/AntiFlg:%  IllCat:%  CanType:%  Cells:%  prod#:%  Target#:935  State#:%  Dir#:1
  wNotes=on  sortOrder:rid,rpid

 

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