Skip navigation

Chemical Oligosaccharides

1–50 of 169 results.
  Chemical Phenotype Co-Mentioned Terms Interaction Organisms Anatomy Inference Network References
1. 6,6'-bis(2,3-dimethoxybenzoyl)-alpha,alpha-trehalose cell migration 6,6'-bis(2,3-dimethoxybenzoyl)-alpha,alpha-trehalose analog results in decreased cell migration 1: Mus musculus Skin | Cell Line, Tumor
2 genes: GSK3B | VEGFA
1
2. Acarbose regulation of blood pressure Dietary Sucrose | Sodium Chloride, Dietary Acarbose inhibits the reaction [[Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in increased regulation of blood pressure] 1: Rattus norvegicus Cardiovascular System
2 genes: LEP | NPY
1
3. Acarbose positive regulation of urine volume Dietary Sucrose | Sodium Chloride, Dietary Acarbose inhibits the reaction [[Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in decreased positive regulation of urine volume] 1: Rattus norvegicus Cardiovascular System   1
4. Acarbose renal sodium excretion Dietary Sucrose | Sodium Chloride, Dietary Acarbose inhibits the reaction [[Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in decreased renal sodium excretion] 1: Rattus norvegicus Cardiovascular System   1
5. Acarbose regulation of blood pressure Acarbose results in decreased regulation of blood pressure 1: Homo sapiens Cardiovascular System
2 genes: LEP | NPY
1
6. Acarbose response to oxidative stress Acarbose results in decreased response to oxidative stress 1: Mus musculus Heart Ventricles | Myocardium   1
7. Acarbose alpha-amylase activity Acarbose results in decreased alpha-amylase activity 1: Sus scrofa Pancreas   1
8. baicalein-7-O-diglucoside response to endoplasmic reticulum stress baicalein-7-O-diglucoside results in increased response to endoplasmic reticulum stress 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor
2 genes: DDIT3 | HSPA5
1
9. baicalein-7-O-diglucoside positive regulation of p38MAPK cascade baicalein-7-O-diglucoside results in increased positive regulation of p38MAPK cascade 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor   1
10. baicalein-7-O-diglucoside positive regulation of apoptotic process baicalein-7-O-diglucoside results in increased positive regulation of apoptotic process 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor
2 genes: ATF6 | DDIT3
1
11. baicalein-7-O-diglucoside positive regulation of cell proliferation baicalein-7-O-diglucoside results in decreased positive regulation of cell proliferation 1: Homo sapiens Cell Line, Tumor   1
12. baicalein-7-O-diglucoside positive regulation of p38MAPK cascade SB 203580 SB 203580 inhibits the reaction [baicalein-7-O-diglucoside results in increased positive regulation of p38MAPK cascade] 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor   1
13. baicalein-7-O-diglucoside positive regulation of apoptotic process SB 203580 SB 203580 inhibits the reaction [baicalein-7-O-diglucoside results in increased positive regulation of apoptotic process] 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor
2 genes: ATF6 | DDIT3
1
14. cynatratoside-C lipid catabolic process Lipopolysaccharides cynatratoside-C inhibits the reaction [Lipopolysaccharides results in increased lipid catabolic process] 1: Mus musculus Mammary Glands, Animal   1
15. cynatratoside-C glutathione peroxidase activity Lipopolysaccharides cynatratoside-C inhibits the reaction [Lipopolysaccharides results in increased glutathione peroxidase activity] 1: Mus musculus Mammary Glands, Animal   1
16. cynatratoside-C superoxide dismutase activity Lipopolysaccharides cynatratoside-C inhibits the reaction [Lipopolysaccharides results in increased superoxide dismutase activity] 1: Mus musculus Mammary Glands, Animal   1
17. cynatratoside-C leukocyte migration involved in inflammatory response Lipopolysaccharides cynatratoside-C inhibits the reaction [Lipopolysaccharides results in increased leukocyte migration involved in inflammatory response] 1: Mus musculus Mammary Glands, Animal   1
18. Dietary Sucrose regulation of blood pressure Acarbose | Sodium Chloride, Dietary Acarbose inhibits the reaction [[Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in increased regulation of blood pressure] 1: Rattus norvegicus Cardiovascular System
13 genes: ACSM3 | CYP4F18 | EPHX2 | HMOX1 | LEP | NOS2 | NOS3 | NPPA | NPPB | NPY | PPARG | SOD1 | SOD2
1
19. Dietary Sucrose regulation of blood pressure Sodium Chloride, Dietary [Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in increased regulation of blood pressure 1: Rattus norvegicus Cardiovascular System
13 genes: ACSM3 | CYP4F18 | EPHX2 | HMOX1 | LEP | NOS2 | NOS3 | NPPA | NPPB | NPY | PPARG | SOD1 | SOD2
1
20. Dietary Sucrose positive regulation of urine volume Sodium Chloride, Dietary [Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in decreased positive regulation of urine volume 1: Rattus norvegicus Cardiovascular System
2 genes: HAS2 | NPPB
1
21. Dietary Sucrose positive regulation of urine volume Acarbose | Sodium Chloride, Dietary Acarbose inhibits the reaction [[Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in decreased positive regulation of urine volume] 1: Rattus norvegicus Cardiovascular System
2 genes: HAS2 | NPPB
1
22. Dietary Sucrose renal sodium excretion Sodium Chloride, Dietary [Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in decreased renal sodium excretion 1: Rattus norvegicus Cardiovascular System   1
23. Dietary Sucrose renal sodium excretion Acarbose | Sodium Chloride, Dietary Acarbose inhibits the reaction [[Dietary Sucrose co-treated with Sodium Chloride, Dietary] results in decreased renal sodium excretion] 1: Rattus norvegicus Cardiovascular System   1
24. Dietary Sucrose response to oxidative stress Dietary Sucrose results in increased response to oxidative stress 1: Rattus norvegicus  
22 genes: ALDH1A1 | CAR3 | CAT | CST3 | DGKK | DUOX2 | GPX1 | GPX4 | GSR | HMOX1 | LCN2 | MT3 | NQO1 | PRDX6 | SCARA3 | SIRT1 | SLC7A11 | SOD1 | SOD2 | TPO | TRP53 | VNN1
1
25. Dietary Sucrose lipid catabolic process Dietary Sucrose results in decreased lipid catabolic process 1: Rattus norvegicus  
16 genes: APOA4 | CLPS | CYP39A1 | ENPP6 | LIPF | MGLL | PCK1 | PLA1A | PLA2G10 | PLA2G7 | PLCD4 | PLCXD2 | PLIN1 | PNLIP | PNPLA2 | PRDX6
1
26. Dietary Sucrose response to oxidative stress Acetylcysteine Acetylcysteine inhibits the reaction [Dietary Sucrose results in increased response to oxidative stress] 1: Rattus norvegicus  
22 genes: ALDH1A1 | CAR3 | CAT | CST3 | DGKK | DUOX2 | GPX1 | GPX4 | GSR | HMOX1 | LCN2 | MT3 | NQO1 | PRDX6 | SCARA3 | SIRT1 | SLC7A11 | SOD1 | SOD2 | TPO | TRP53 | VNN1
1
27. Dietary Sucrose lipid catabolic process Acetylcysteine Acetylcysteine inhibits the reaction [Dietary Sucrose results in decreased lipid catabolic process] 1: Rattus norvegicus  
16 genes: APOA4 | CLPS | CYP39A1 | ENPP6 | LIPF | MGLL | PCK1 | PLA1A | PLA2G10 | PLA2G7 | PLCD4 | PLCXD2 | PLIN1 | PNLIP | PNPLA2 | PRDX6
1
28. Dietary Sucrose response to oxidative stress Dietary Sucrose results in increased response to oxidative stress 1: Rattus norvegicus Heart
22 genes: ALDH1A1 | CAR3 | CAT | CST3 | DGKK | DUOX2 | GPX1 | GPX4 | GSR | HMOX1 | LCN2 | MT3 | NQO1 | PRDX6 | SCARA3 | SIRT1 | SLC7A11 | SOD1 | SOD2 | TPO | TRP53 | VNN1
1
29. Dietary Sucrose response to oxidative stress Acetylcysteine Acetylcysteine inhibits the reaction [Dietary Sucrose results in increased response to oxidative stress] 1: Rattus norvegicus Heart
22 genes: ALDH1A1 | CAR3 | CAT | CST3 | DGKK | DUOX2 | GPX1 | GPX4 | GSR | HMOX1 | LCN2 | MT3 | NQO1 | PRDX6 | SCARA3 | SIRT1 | SLC7A11 | SOD1 | SOD2 | TPO | TRP53 | VNN1
1
30. Dietary Sucrose lipid catabolic process Dietary Sucrose results in decreased lipid catabolic process 1: Rattus norvegicus Heart
16 genes: APOA4 | CLPS | CYP39A1 | ENPP6 | LIPF | MGLL | PCK1 | PLA1A | PLA2G10 | PLA2G7 | PLCD4 | PLCXD2 | PLIN1 | PNLIP | PNPLA2 | PRDX6
1
31. Dietary Sucrose lipid catabolic process Acetylcysteine Acetylcysteine inhibits the reaction [Dietary Sucrose results in decreased lipid catabolic process] 1: Rattus norvegicus Heart
16 genes: APOA4 | CLPS | CYP39A1 | ENPP6 | LIPF | MGLL | PCK1 | PLA1A | PLA2G10 | PLA2G7 | PLCD4 | PLCXD2 | PLIN1 | PNLIP | PNPLA2 | PRDX6
1
32. Dietary Sucrose triglyceride biosynthetic process Dietary Fats [Dietary Fats co-treated with Dietary Sucrose] results in increased triglyceride biosynthetic process 2: Mus musculus | Rattus norvegicus Liver
4 genes: ACSL4 | DGAT2 | LPIN1 | MOGAT1
2
33. Dietary Sucrose triglyceride biosynthetic process Betaine | Choline | Dietary Fats | Folic Acid | Vitamin B 12 [Choline co-treated with Betaine co-treated with Vitamin B 12 co-treated with Folic Acid] inhibits the reaction [[Dietary Fats co-treated with Dietary Sucrose] results in increased triglyceride biosynthetic process] 1: Rattus norvegicus Liver
4 genes: ACSL4 | DGAT2 | LPIN1 | MOGAT1
1
34. Dietary Sucrose detection of glucose Dietary Fats [Dietary Fats co-treated with Dietary Sucrose] results in increased detection of glucose 1: Rattus norvegicus Plasma
2 genes: GCK | NKX6-1
1
35. Dietary Sucrose DNA damage response, detection of DNA damage Dietary Sucrose results in increased DNA damage response, detection of DNA damage 1: Rattus norvegicus Colon   1
36. Dietary Sucrose cellular senescence Dietary Fats [Dietary Fats co-treated with Dietary Sucrose] results in increased cellular senescence 1: Rattus norvegicus Aorta
4 genes: CAV1 | CDKN1A | ID2 | PML
1
37. Dietary Sucrose cellular senescence Dietary Fats | Resveratrol Resveratrol inhibits the reaction [[Dietary Fats co-treated with Dietary Sucrose] results in increased cellular senescence] 1: Rattus norvegicus Aorta
4 genes: CAV1 | CDKN1A | ID2 | PML
1
38. Dietary Sucrose mitochondrial electron transport, cytochrome c to oxygen Copper [Dietary Sucrose co-treated with Copper deficiency] results in decreased mitochondrial electron transport, cytochrome c to oxygen 1: Rattus norvegicus Islets of Langerhans | Cells, Cultured   1
39. Dietary Sucrose positive regulation of insulin secretion involved in cellular response to glucose stimulus Copper [Dietary Sucrose co-treated with Copper deficiency] results in decreased positive regulation of insulin secretion involved in cellular response to glucose stimulus 1: Rattus norvegicus Islets of Langerhans | Cells, Cultured
6 genes: ATG7 | GHRL | GPR27 | HIF1A | NR1H4 | SIRT1
1
40. Dietary Sucrose mitochondrial electron transport, cytochrome c to oxygen Copper Copper inhibits the reaction [[Dietary Sucrose co-treated with Copper deficiency] results in decreased mitochondrial electron transport, cytochrome c to oxygen] 1: Rattus norvegicus Islets of Langerhans | Cells, Cultured   1
41. Dietary Sucrose positive regulation of insulin secretion involved in cellular response to glucose stimulus Copper Copper inhibits the reaction [[Dietary Sucrose co-treated with Copper deficiency] results in decreased positive regulation of insulin secretion involved in cellular response to glucose stimulus] 1: Rattus norvegicus Islets of Langerhans | Cells, Cultured
6 genes: ATG7 | GHRL | GPR27 | HIF1A | NR1H4 | SIRT1
1
42. Dietary Sucrose positive regulation of insulin secretion involved in cellular response to glucose stimulus Copper [Dietary Sucrose co-treated with Copper deficiency] results in decreased positive regulation of insulin secretion involved in cellular response to glucose stimulus 1: Rattus norvegicus Insulin-Secreting Cells
6 genes: ATG7 | GHRL | GPR27 | HIF1A | NR1H4 | SIRT1
1
43. Dietary Sucrose mitochondrial electron transport, cytochrome c to oxygen Copper [Dietary Sucrose co-treated with Copper deficiency] results in decreased mitochondrial electron transport, cytochrome c to oxygen 1: Rattus norvegicus Islets of Langerhans   1
44. Dietary Sucrose positive regulation of macrophage activation Copper [Dietary Sucrose co-treated with Copper deficiency] results in increased positive regulation of macrophage activation 1: Rattus norvegicus Pancreas, Exocrine
2 genes: HAVCR2 | LBP
1
45. Dietary Sucrose positive regulation of macrophage chemotaxis Copper [Dietary Sucrose co-treated with Copper deficiency] results in increased positive regulation of macrophage chemotaxis 1: Rattus norvegicus Pancreas, Exocrine 1 gene: CCL2 1
46. Dietary Sucrose positive regulation of insulin secretion involved in cellular response to glucose stimulus Copper Copper inhibits the reaction [[Dietary Sucrose co-treated with Copper deficiency] results in decreased positive regulation of insulin secretion involved in cellular response to glucose stimulus] 1: Rattus norvegicus Insulin-Secreting Cells
6 genes: ATG7 | GHRL | GPR27 | HIF1A | NR1H4 | SIRT1
1
47. Dietary Sucrose mitochondrial electron transport, cytochrome c to oxygen Copper Copper inhibits the reaction [[Dietary Sucrose co-treated with Copper deficiency] results in decreased mitochondrial electron transport, cytochrome c to oxygen] 1: Rattus norvegicus Islets of Langerhans   1
48. Dietary Sucrose positive regulation of macrophage activation Copper Copper inhibits the reaction [[Dietary Sucrose co-treated with Copper deficiency] results in increased positive regulation of macrophage activation] 1: Rattus norvegicus Pancreas, Exocrine
2 genes: HAVCR2 | LBP
1
49. Dietary Sucrose positive regulation of macrophage chemotaxis Copper Copper inhibits the reaction [[Dietary Sucrose co-treated with Copper deficiency] results in increased positive regulation of macrophage chemotaxis] 1: Rattus norvegicus Pancreas, Exocrine 1 gene: CCL2 1
50. Dietary Sucrose lipid catabolic process Copper [Copper deficiency co-treated with Dietary Sucrose] results in increased lipid catabolic process 1: Rattus norvegicus Liver
16 genes: APOA4 | CLPS | CYP39A1 | ENPP6 | LIPF | MGLL | PCK1 | PLA1A | PLA2G10 | PLA2G7 | PLCD4 | PLCXD2 | PLIN1 | PNLIP | PNPLA2 | PRDX6
1
1–50 of 169 results.