| Features: |
| Sulforaphane is an isothiocyanate derived from glucoraphanin, a compound found predominantly in cruciferous vegetables such as broccoli, Brussels sprouts, and cabbage. It is well known for its potent antioxidant and detoxification properties and has gained significant attention for its potential chemopreventive and anticancer effects. Summary 1.primarily attenuates both DNMTs and HDACs, individually suppressing DNA hypermethylation and histones deacetylation, ultimately upregulating NRF2 (best known for NRF2↑) 2.Antioxidant Activity: • Nrf2 activation leads to the upregulation of a host of antioxidant and detoxification enzymes (e.g., glutathione S-transferase, NAD(P)H:quinone oxidoreductase 1, heme oxygenase-1), which in turn decrease oxidative stress and lower ROS levels. 3.Pro-oxidant Effects in Cancer Cells and Under High-Dose Conditions (>=10uM?) • In certain cancer cell types or at higher concentrations, sulforaphane can paradoxically lead to an increase in ROS levels. • The elevated ROS may overwhelm the cancer cells’ antioxidant defenses, leading to oxidative stress–mediated cell death (apoptosis). • This context-dependent pro-oxidant effect has been explored for its potential in selectively targeting cancer cells while leaving normal cells less affected. - Might not be a good candidate for pro-oxidant strategy depending on concentration >10uM?. - Strong Activation of Nrf2 (best known for) at low to moderate concentrations, hence reduces oxidative stress in both cancer and normal cells. - AMPK signaling activated by SFN, high concentrations of ROS are produced - ROS generation also results in depletion of GSH levels - HIF-1α and VEGF inhibitor - Might be effective against cancer stem cells - But I would not combine that with radiation, as Sulforaphane activates the anti-oxidant master regulator of cells. - “I very much agree: Sulforaphane is a very good addition, even more when the choice is an anti-oxidant therapy” - well known as HDAC inhibitor (typically 5-10um concentrations) -A transient decrease in HDAC activity has also been observed in healthy humans 3 h after providing a daily 200 µM SFN dose, resulting in a plasma concentration of SFN metabolites of 0.1–0.2 µM. Dose/Bioavailabilty information: SFN at a daily dose of 2.2 µM/kg body weight, with a mean plasma level of 0.13 µM Sprout 127.6 grams = 205uM±19.9 content yields SFN 0.5 to 2uM in plasma. However, it is important to consider that at lower doses, specifically 2.5 μM, SFN resulted in a slight increase in cell proliferation by 5.18–11.84% within a 6 to 48 h treatment window. -A therapeutic dose starts at approx 60 grams of the sprouts. -100 g of Broccoli sprouts contain about 15–20 mg of sulforaphane –Organic Broccoli Sprout Powder (Health Ranger) – Avmacol® – NanoPSA (a blend of NanoStilbene™ and Broccoli Sprout Extract). - -750 mg Sulforaphane Glucosinolate in Daily One Serving (2 capsules) (30mg Sulforaphane) Total sulforaphane metabolite concentration in plasma was the highest (>2 μM) at 3 h in human subjects who consumed fresh broccoli sprouts (40g) -human studies with broccoli sprouts or extracts report plasma sulforaphane levels in the low micromolar range (typically 1–2 µM) after ingesting realistic, food-based quantities of sprouts (often in the range of 30–50 g of sprouts or a concentrated extract). BroccoSprouts are young broccoli sprouts that have garnered attention because they contain high amounts of glucoraphanin—a precursor molecule to sulforaphane. Studies have shown that broccoli sprouts can have sulforaphane precursor levels (i.e., glucoraphanin levels) that are 10 to 100 times higher than those found in mature broccoli heads. Glucoraphanin content in broccoli sprouts can range anywhere from about 30 to over 100 mg per 100 grams of fresh sprouts. Once activated (e.g., during consumption when myrosinase acts on glucoraphanin), these levels translate into a significant sulforaphane yield, meaning that even a small amount of broccoli sprouts can deliver a potent dose of this bioactive compound. Importantly, glucoraphanin itself is not bioactive. Rather, enzymatic hydrolysis by myrosinase, present in the plant tissue or in the mammalian microbiome, is necessary to form the active component, SFN. - GFN (glucoraphanin) is hydrolyzed in vivo to SFN via the myrosinase, which is present in gut bacteria as well as the plant itself (also in Radish) - Do not cook the vegetables, or if you do add myrosinase back in by adding radish. - mild heat of broccoli (60–70 °C) inactivated ESP and preserved myrosinase and increased SF yield 3–7-fold - chewing of fresh broccoli sprouts increases the interaction of glucosinolates with myrosinase and consequently, increases the bioavailability of SFN in the body -Note half-life 2-3 hrs. BioAv is good (15-80%) but requires myrosinase Pathways: - induce ROS production - ROS↑ related: MMP↓(ΔΨm), ER Stress↑, UPR↑, GRP78↑, Ca+2↑, Cyt‑c↑, Caspases↑, DNA damage↑, cl-PARP↑, HSP↓, Prx, - Lowers AntiOxidant defense in Cancer Cells: NRF2↓(contrary, actually most raises NRF2), TrxR↓**, GSH↓, Catalase↓(contrary), HO1↓(contrary), GPx↓ - Raises AntiOxidant defense in Normal Cells: ROS↓, NRF2↑, SOD↑, GSH↑, Catalase↑, - lowers Inflammation : NF-kB↓, COX2↓, p38↓, Pro-Inflammatory Cytokines : NLRP3↓, IL-1β↓, TNF-α↓, IL-6↓, IL-8↓ - inhibit Growth/Metastases : TumMeta↓, TumCG↓, EMT↓, MMPs↓, MMP2↓, MMP9↓, IGF-1↓, VEGF↓, ROCK1↓, FAK↓, RhoA↓, NF-κB↓, CXCR4↓, α-SMA↓, ERK↓ - reactivate genes thereby inhibiting cancer cell growth : HDAC↓, DNMTs↓, EZH2↓, P53↑, HSP↓, Sp proteins↓, - cause Cell cycle arrest : TumCCA↑, cyclin D1↓, cyclin E↓, CDK2↓, CDK4↓, CDK6↓, - inhibits Migration/Invasion : TumCMig↓, TumCI↓, TNF-α↓, FAK↓, ERK↓, EMT↓, - inhibits glycolysis /Warburg Effect and ATP depletion : HIF-1α↓, PKM2↓, cMyc↓, GLUT1↓, LDH↓, LDHA↓, HK2↓, ECAR↓, OXPHOS↓, GRP78↑, GlucoseCon↓ - inhibits angiogenesis↓ : VEGF↓, HIF-1α↓, Notch↓, PDGF↓, EGFR↓, Integrins↓, - inhibits Cancer Stem Cells : CSC↓, Hh↓, GLi↓, GLi1↓, CD133↓, β-catenin↓, sox2↓, notch2↓, nestin↓, OCT4↓, - Others: PI3K↓, AKT↓, JAK↓, STAT↓, Wnt↓, β-catenin↓, AMPK, ERK↓, 5↓, - SREBP (related to cholesterol). - Synergies: chemo-sensitization, chemoProtective, RadioSensitizer, RadioProtective, Others(review target notes), Neuroprotective, Cognitive, Renoprotection, Hepatoprotective, CardioProtective, - Selectivity: Cancer Cells vs Normal Cells |
| Source: |
| Type: enzyme |
| PKM2 (Pyruvate Kinase, Muscle 2) is an enzyme that plays a crucial role in glycolysis, the process by which cells convert glucose into energy. PKM2 is a key regulatory enzyme in the glycolytic pathway, and it is primarily expressed in various tissues, including muscle, brain, and cancer cells. -C-myc is a common oncogene that enhances aerobic glycolysis in the cancer cells by transcriptionally activating GLUT1, HK2, PKM2 and LDH-A -PKM2 has been shown to be overexpressed in many types of tumors, including breast, lung, and colon cancer. This overexpression may contribute to the development and progression of cancer by promoting glycolysis and energy production in cancer cells. -inhibition of PKM2 may cause ATP depletion and inhibiting glycolysis. -PK exists in four isoforms: PKM1, PKM2, PKR, and PKL -PKM2 plays a role in the regulation of glucose metabolism in diabetes. -PKM2 is involved in the regulation of cell proliferation, apoptosis, and autophagy. – Pyruvate kinase catalyzes the final, rate-limiting step of glycolysis, converting phosphoenolpyruvate (PEP) to pyruvate with the production of ATP. – The PKM2 isoform is uniquely regulated and can exist in both highly active tetrameric and less active dimeric forms. – Cancer cells often favor the dimeric form of PKM2 to slow pyruvate production, thereby accumulating upstream glycolytic intermediates that can be diverted into anabolic pathways to support cell growth and proliferation. – Under low oxygen conditions, cancer cells rely on altered metabolic pathways in which PKM2 is a key player. – The shift to aerobic glycolysis (Warburg effect) orchestrated in part by PKM2 helps tumor cells survive and grow in hypoxic conditions. – Elevated expression of PKM2 is frequently observed in many cancer types, including lung, breast, colorectal, and pancreatic cancers. – High levels of PKM2 are often correlated with enhanced tumor aggressiveness, poor differentiation, and advanced clinical stage. PKM2 in carcinogenesis and oncotherapy Inhibitors of PKM2: -Shikonin, Resveratrol, Baicalein, EGCG, Apigenin, Curcumin, Ursolic Acid, Citrate (best known as an allosteric inhibitor of phosphofructokinase-1 (PFK-1), a key rate-limiting enzyme in glycolysis) potential to directly inhibit or modulate PKM2 is less well established Full List of PKM2 inhibitors from Database -key connected observations: Glycolysis↓, lactateProd↓, ROS↑ in cancer cell, while some result for opposite effect on normal cells. Tumor pyruvate kinase M2 modulators Flavonoids effect on PKM2 Compounds name IC50/AC50uM Effect Flavonols 1. Fisetin 0.90uM Inhibition 2. Rutin 7.80uM Inhibition 3. Galangin 8.27uM Inhibition 4. Quercetin 9.24uM Inhibition 5. Kaempferol 9.88uM Inhibition 6. Morin hydrate 37.20uM Inhibition 7. Myricetin 0.51uM Activation 8. Quercetin 3-b- D-glucoside 1.34uM Activation 9. Quercetin 3-D -galactoside 27-107uM Ineffective Flavanons 10. Neoeriocitrin 0.65uM Inhibition 11. Neohesperidin 14.20uM Inhibition 12. Naringin 16.60uM Inhibition 13. Hesperidin 17.30uM Inhibition 14. Hesperitin 29.10uM Inhibition 15. Naringenin 70.80uM Activation Flavanonols 16. (-)-Catechin gallateuM 0.85 Inhibition 17. (±)-Taxifolin 1.16uM Inhibition 18. (-)-Epicatechin 1.33uM Inhibition 19. (+)-Gallocatechin 4-16uM Ineffective Phenolic acids 20. Ferulic 11.4uM Inhibition 21. Syringic and 13.8uM Inhibition 22. Caffeic acid 36.3uM Inhibition 23. 3,4-Dihydroxybenzoic acid 78.7uM Inhibition 24. Gallic acid 332.6uM Inhibition 25. Shikimic acid 990uM Inhibition 26. p-Coumaric acid 22.2uM Activation 27. Sinapinic acids 26.2uM Activation 28. Vanillic 607.9uM Activation |
| 2403- | SFN, | Reversal of the Warburg phenomenon in chemoprevention of prostate cancer by sulforaphane |
| - | in-vitro, | Pca, | LNCaP | - | in-vitro, | Pca, | 22Rv1 | - | in-vitro, | Pca, | PC3 | - | in-vivo, | NA, | NA |
| 2404- | SFN, | Prostate cancer chemoprevention by sulforaphane in a preclinical mouse model is associated with inhibition of fatty acid metabolism |
| - | in-vitro, | Pca, | LNCaP | - | in-vitro, | Pca, | 22Rv1 | - | in-vivo, | NA, | NA |
| 2405- | SFN, | Sulforaphane Targets the TBX15/KIF2C Pathway to Repress Glycolysis and Cell Proliferation in Gastric Carcinoma Cells |
| - | in-vitro, | GC, | SGC-7901 | - | in-vitro, | GC, | BGC-823 |
| 2406- | SFN, | Sulforaphane and Its Protective Role in Prostate Cancer: A Mechanistic Approach |
| - | Review, | Pca, | NA |
| 2445- | SFN, | Sulforaphane-Induced Cell Cycle Arrest and Senescence are accompanied by DNA Hypomethylation and Changes in microRNA Profile in Breast Cancer Cells |
| - | in-vitro, | BC, | MCF-7 | - | in-vitro, | BC, | MDA-MB-231 | - | in-vitro, | BC, | SkBr3 |
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