cycloheximide has been researched along with quercetin in 16 studies
| Timeframe | Studies, this research(%) | All Research% |
|---|---|---|
| pre-1990 | 1 (6.25) | 18.7374 |
| 1990's | 4 (25.00) | 18.2507 |
| 2000's | 7 (43.75) | 29.6817 |
| 2010's | 3 (18.75) | 24.3611 |
| 2020's | 1 (6.25) | 2.80 |
| Authors | Studies |
|---|---|
| Ghosh, I; Manoharlal, R; Prakash, O; Prasad, R; Puri, N; Sharma, M | 1 |
| Batista-Gonzalez, A; Brunhofer, G; Fallarero, A; Gopi Mohan, C; Karlsson, D; Shinde, P; Vuorela, P | 1 |
| Easwaran, M; Manickam, M; Pillaiyar, T; Wendt, LL | 1 |
| Nikaido, T; Yamamoto, M; Yoshida, M | 1 |
| Abe, M; Hiraoka, M; Hirayoshi, K; Hosokawa, N; Koishi, M; Nagata, K; Nakai, A; Sato, M | 1 |
| Borrelli, MJ; Corry, PM; Curetty, L; Hou, ZZ; Lee, YJ | 1 |
| Carrasco, L; Guinea, R; López-Rivas, A | 1 |
| Fukata, H; Kariya, Y; Teshigawara, K; Uchida, A; Wei, YQ; Zhao, X | 1 |
| Cantabrana, B; Hidalgo, A; Revuelta, MP | 1 |
| Busányová, K; Drobná, Z; Ferencík, M; Horáková, K; Seemannová, Z; Sovcíková, A; Syrová, D | 1 |
| Alhava, E; Oksala, A; Oksala, NK; Paavonen, T; Paimela, H | 1 |
| Homma, T; Nagata, H; Takekoshi, S; Takeyama, R; Yoshiyuki Osamura, R | 1 |
| Chen, YC; Cheng, TH; Juan, SH; Lin, HC | 1 |
| Gajkowska, B; Orzechowski, A; Pajak, B | 1 |
| Bowles, DJ; Brown, GD; Brown, N; Drummond, RA; Kaye, PM; Lim, EK; Mitchell, PJ | 1 |
| Bellows, DS; Clarke, ID; Diamandis, P; Dirks, PB; Graham, J; Jamieson, LG; Ling, EK; Sacher, AG; Tyers, M; Ward, RJ; Wildenhain, J | 1 |
1 review(s) available for cycloheximide and quercetin
| Article | Year |
|---|---|
The recent outbreaks of human coronaviruses: A medicinal chemistry perspective.
Topics: Antiviral Agents; Chemistry, Pharmaceutical; COVID-19; Disease Outbreaks; Drug Repositioning; Humans; Virus Internalization | 2021 |
15 other study(ies) available for cycloheximide and quercetin
| Article | Year |
|---|---|
Analysis of physico-chemical properties of substrates of ABC and MFS multidrug transporters of pathogenic Candida albicans.
Topics: Candida albicans; Membrane Transport Proteins; Saccharomyces cerevisiae; Structure-Activity Relationship; Substrate Specificity | 2010 |
Exploration of natural compounds as sources of new bifunctional scaffolds targeting cholinesterases and beta amyloid aggregation: the case of chelerythrine.
Topics: Acetylcholinesterase; Amyloid beta-Peptides; Benzophenanthridines; Binding Sites; Butyrylcholinesterase; Catalytic Domain; Cholinesterase Inhibitors; Humans; Isoquinolines; Kinetics; Molecular Docking Simulation; Structure-Activity Relationship | 2012 |
Quercetin arrests human leukemic T-cells in late G1 phase of the cell cycle.
Topics: Aphidicolin; CDC2 Protein Kinase; Cyclins; Cycloheximide; DNA, Neoplasm; Flow Cytometry; G1 Phase; Histones; Humans; Leukemia, T-Cell; Mimosine; Quercetin; RNA, Messenger; RNA, Neoplasm; S Phase; Time Factors; Tumor Cells, Cultured | 1992 |
Quercetin, an inhibitor of heat shock protein synthesis, inhibits the acquisition of thermotolerance in a human colon carcinoma cell line.
Topics: Arsenic; Arsenites; Colonic Neoplasms; Cycloheximide; Heat-Shock Proteins; Humans; Hyperthermia, Induced; Kinetics; Quercetin; RNA Polymerase II; Sodium Compounds; Time Factors; Tumor Cells, Cultured | 1992 |
Correlation between redistribution of a 26 kDa protein and development of chronic thermotolerance in various mammalian cell lines.
Topics: Animals; Biological Transport; Carbocyanines; Cell Line; Cell Nucleus; Cell Survival; Cricetinae; Cricetulus; Cycloheximide; Female; Heat-Shock Proteins; HeLa Cells; Hot Temperature; Humans; Molecular Weight; Nuclear Proteins; Quercetin; Time Factors | 1990 |
Modification of phospholipase C and phospholipase A2 activities during poliovirus infection.
Topics: Antiviral Agents; Arachidonic Acid; Arachidonic Acids; Calcimycin; Cell Transformation, Viral; Cycloheximide; Flavonols; HeLa Cells; Humans; Hygromycin B; Inositol 1,4,5-Trisphosphate; Inositol Phosphates; Kinetics; Phospholipases; Phospholipases A; Phospholipases A2; Poliovirus; Quercetin; Type C Phospholipases | 1989 |
Induction of apoptosis by quercetin: involvement of heat shock protein.
Topics: Apoptosis; Base Sequence; Cycloheximide; Dactinomycin; Dose-Response Relationship, Drug; G1 Phase; Heat-Shock Proteins; Hot Temperature; Humans; Molecular Sequence Data; Quercetin; S Phase; Time Factors; Tumor Cells, Cultured | 1994 |
Mechanisms involved in kaempferol-induced relaxation in rat uterine smooth muscle.
Topics: Adenylyl Cyclase Inhibitors; Animals; Antimetabolites; Cyclic AMP; Cyclic AMP-Dependent Protein Kinases; Cycloheximide; Dactinomycin; Dideoxyadenosine; Drug Synergism; Eflornithine; Enzyme Inhibitors; Female; Flavonoids; In Vitro Techniques; Kaempferols; Muscle Relaxation; Muscle, Smooth; Papaverine; Phosphodiesterase Inhibitors; Potassium Chloride; Protein Synthesis Inhibitors; Quercetin; Rats; Rats, Wistar; Serine Proteinase Inhibitors; Spermine; Thionucleotides; Tosylphenylalanyl Chloromethyl Ketone; Uterine Contraction; Uterus | 2000 |
Detection of drug-induced, superoxide-mediated cell damage and its prevention by antioxidants.
Topics: Antioxidants; Benzo(a)pyrene; Cell Division; Cell Survival; Citrinin; Colorimetry; Cycloheximide; Cyclosporine; Dose-Response Relationship, Drug; Enzyme-Linked Immunosorbent Assay; Fluorenes; Formazans; HeLa Cells; Humans; Lysosomes; Mitochondria; Oxidoreductases; Quercetin; Superoxide Dismutase; Superoxides; Tetrazolium Salts; Toxicity Tests; Xenobiotics | 2001 |
Heat shock preconditioning modulates proliferation and apoptosis after superficial injury in isolated guinea pig gastric mucosa via an eicosanoid and protein synthesis-dependent mechanism.
Topics: Animals; Apoptosis; Arachidonic Acid; bcl-2-Associated X Protein; Cell Division; Cycloheximide; Enzyme Inhibitors; Gastric Mucosa; Guinea Pigs; Heat-Shock Response; Hyperthermia, Induced; Immunohistochemistry; In Vitro Techniques; Indomethacin; Ki-67 Antigen; Protein Synthesis Inhibitors; Proto-Oncogene Proteins; Proto-Oncogene Proteins c-bcl-2; Quercetin; Wound Healing | 2003 |
Quercetin enhances melanogenesis by increasing the activity and synthesis of tyrosinase in human melanoma cells and in normal human melanocytes.
Topics: Animals; Cells, Cultured; Cycloheximide; Dactinomycin; Flavonoids; Gene Expression Regulation, Enzymologic; Humans; Melanins; Melanocytes; Melanoma; Monophenol Monooxygenase; Quercetin | 2004 |
Mechanism of heme oxygenase-1 gene induction by quercetin in rat aortic smooth muscle cells.
Topics: Animals; Blotting, Northern; Blotting, Western; Cells, Cultured; Cycloheximide; Dactinomycin; Dose-Response Relationship, Drug; Gene Expression Regulation; Guinea Pigs; Heme Oxygenase (Decyclizing); Heme Oxygenase-1; Imidazoles; Male; MAP Kinase Signaling System; p38 Mitogen-Activated Protein Kinases; Phosphorylation; Protein Biosynthesis; Pyridines; Quercetin; Rats; Rats, Sprague-Dawley; RNA, Messenger; Time Factors; Transcription, Genetic; Transcriptional Activation | 2004 |
Position of STAT-1 alpha in cycloheximide-dependent apoptosis triggered by TNF-alpha in human colorectal COLO 205 cancer cell line; role of polyphenolic compounds.
Topics: Apigenin; Apoptosis; CASP8 and FADD-Like Apoptosis Regulating Protein; Cell Line, Tumor; Cell Proliferation; Cell Survival; Chromones; Colorectal Neoplasms; Cycloheximide; Dose-Response Relationship, Drug; Flavonoids; Humans; Interferon-Stimulated Gene Factor 3; Kaempferols; Ligands; MAP Kinase Kinase Kinases; Morpholines; Phenols; Phosphatidylinositol 3-Kinases; Phosphoinositide-3 Kinase Inhibitors; Phosphorylation; Polyphenols; Protein Kinase Inhibitors; Protein Synthesis Inhibitors; Quercetin; Receptors, Tumor Necrosis Factor, Type I; Signal Transduction; Time Factors; Tumor Escape; Tumor Necrosis Factor-alpha | 2005 |
Regiospecific methylation of a dietary flavonoid scaffold selectively enhances IL-1β production following Toll-like receptor 2 stimulation in THP-1 monocytes.
Topics: Caspase 1; Cell Line; Cycloheximide; Drug Synergism; Flavonoids; Gene Expression Regulation; Humans; Interleukin-1beta; Lipopeptides; Methylation; Mitogen-Activated Protein Kinases; Models, Biological; Monocytes; Phosphorylation; Quercetin; RNA, Messenger; Stereoisomerism; Toll-Like Receptor 2; Transcription, Genetic | 2013 |
Chemical genetics reveals a complex functional ground state of neural stem cells.
Topics: Animals; Cell Survival; Cells, Cultured; Mice; Molecular Structure; Neoplasms; Neurons; Pharmaceutical Preparations; Sensitivity and Specificity; Stem Cells | 2007 |