Skip navigation

Chemical Pyrrolizidine Alkaloids

1–50 of 138 results.
  Chemical Phenotype Co-Mentioned Terms Interaction Organisms Anatomy Inference Network References
1. clivorine cell death clivorine results in increased cell death 1: Homo sapiens Liver | Cell Line   1
2. clivorine cell death Quercetin Quercetin inhibits the reaction [clivorine results in increased cell death] 1: Homo sapiens Liver | Cell Line   1
3. clivorine cell death Quercetin | zinc protoporphyrin zinc protoporphyrin inhibits the reaction [Quercetin inhibits the reaction [clivorine results in increased cell death]] 1: Homo sapiens Liver | Cell Line   1
4. clivorine cell death Buthionine Sulfoximine | Quercetin Buthionine Sulfoximine affects the reaction [Quercetin inhibits the reaction [clivorine results in increased cell death]] 1: Homo sapiens Liver | Cell Line   1
5. clivorine cell death Quercetin | SQSTM1 SQSTM1 protein affects the reaction [Quercetin inhibits the reaction [clivorine results in increased cell death]] 1: Homo sapiens Liver | Cell Line   1
6. clivorine cell death pyrazolanthrone | Quercetin pyrazolanthrone inhibits the reaction [Quercetin inhibits the reaction [clivorine results in increased cell death]] 1: Homo sapiens Liver | Cell Line   1
7. echimidine cell growth echimidine results in decreased cell growth 1: Homo sapiens Liver | Cell Line, Tumor   1
8. echimidine apoptotic process echimidine results in increased apoptotic process 1: Homo sapiens Liver | Cell Line, Tumor
4 genes: CASP3 | CASP8 | CASP9 | PARP1
1
9. echimidine regulation of mitochondrial membrane potential echimidine affects regulation of mitochondrial membrane potential 1: Homo sapiens Liver | Cell Line, Tumor   1
10. echimidine nuclear fragmentation involved in apoptotic nuclear change echimidine results in increased nuclear fragmentation involved in apoptotic nuclear change 1: Homo sapiens Liver | Cell Line, Tumor   1
11. echimidine DNA damage response, detection of DNA damage echimidine results in increased DNA damage response, detection of DNA damage 1: Homo sapiens Liver | Cell Line, Tumor 1 gene: PARP1 1
12. heliotrine cell growth heliotrine results in decreased cell growth 1: Homo sapiens Liver | Cell Line, Tumor   1
13. heliotrine apoptotic process heliotrine results in increased apoptotic process 1: Homo sapiens Liver | Cell Line, Tumor
4 genes: CASP3 | CASP8 | CASP9 | PARP1
1
14. heliotrine regulation of mitochondrial membrane potential heliotrine affects regulation of mitochondrial membrane potential 1: Homo sapiens Liver | Cell Line, Tumor   1
15. Monocrotaline vasoconstriction Phenylephrine [Monocrotaline co-treated with Phenylephrine] results in increased vasoconstriction 1: Rattus norvegicus Lung
5 genes: AGT | CAV1 | EDN1 | EDNRA | SLC6A4
1
16. Monocrotaline vasoconstriction Phenylephrine | Propofol [Monocrotaline co-treated with Phenylephrine co-treated with Propofol] results in increased vasoconstriction 1: Rattus norvegicus Lung
5 genes: AGT | CAV1 | EDN1 | EDNRA | SLC6A4
1
17. Monocrotaline vasoconstriction bisindolylmaleimide I | Phenylephrine [Monocrotaline co-treated with bisindolylmaleimide I] inhibits the reaction [Phenylephrine results in increased vasoconstriction] 1: Rattus norvegicus Lung
5 genes: AGT | CAV1 | EDN1 | EDNRA | SLC6A4
1
18. Monocrotaline vasoconstriction bisindolylmaleimide I | Propofol [Monocrotaline co-treated with bisindolylmaleimide I] inhibits the reaction [Propofol results in increased vasoconstriction] 1: Rattus norvegicus Lung
5 genes: AGT | CAV1 | EDN1 | EDNRA | SLC6A4
1
19. Monocrotaline vasoconstriction calphostin C | Propofol [Monocrotaline co-treated with calphostin C] inhibits the reaction [Propofol results in increased vasoconstriction] 1: Rattus norvegicus Lung
5 genes: AGT | CAV1 | EDN1 | EDNRA | SLC6A4
1
20. Monocrotaline reactive oxygen species biosynthetic process Monocrotaline results in increased reactive oxygen species biosynthetic process 1: Rattus norvegicus Pulmonary Artery | Adventitia 1 gene: NOX4 1
21. Monocrotaline cell proliferation Monocrotaline results in increased cell proliferation 1: Rattus norvegicus Fibroblasts
14 genes: AKT1 | BAX | BCL2L1 | CTNNB1 | CXCL1 | EDNRA | IL18 | IL1A | MKI67 | PRKDC | STAT3 | TGFB1 | TXNRD1 | VEGFA
1
22. Monocrotaline reactive oxygen species biosynthetic process Monocrotaline results in increased reactive oxygen species biosynthetic process 1: Rattus norvegicus Pulmonary Artery | Arterioles 1 gene: NOX4 1
23. Monocrotaline regulation of systemic arterial blood pressure Monocrotaline affects regulation of systemic arterial blood pressure 1: Rattus norvegicus   1 gene: POSTN 1
24. Monocrotaline detection of oxidative stress Monocrotaline results in increased detection of oxidative stress 1: Rattus norvegicus     1
25. Monocrotaline regulation of systemic arterial blood pressure Quercetin Quercetin affects the reaction [Monocrotaline affects regulation of systemic arterial blood pressure] 1: Rattus norvegicus   1 gene: POSTN 1
26. Monocrotaline vasodilation Acetylcholine Monocrotaline inhibits the reaction [Acetylcholine results in increased vasodilation] 1: Rattus norvegicus Pulmonary Artery
3 genes: AGT | NOS3 | TNF
1
27. Monocrotaline glutathione derivative biosynthetic process Monocrotaline affects glutathione derivative biosynthetic process 1: Mus musculus Plasma
2 genes: GSTM1 | GSTM3
1
28. Monocrotaline protein modification process Monocrotaline affects protein modification process 1: Mus musculus Liver   1
29. Monocrotaline glutathione derivative biosynthetic process Monocrotaline results in increased glutathione derivative biosynthetic process 1: Mus musculus Liver
2 genes: GSTM1 | GSTM3
1
30. Monocrotaline L-aspartate:2-oxoglutarate aminotransferase activity Monocrotaline results in increased L-aspartate:2-oxoglutarate aminotransferase activity 1: Mus musculus Serum   1
31. Monocrotaline leukocyte migration involved in inflammatory response Monocrotaline results in increased leukocyte migration involved in inflammatory response 1: Mus musculus Serum 1 gene: CCL2 1
32. Monocrotaline positive regulation of extracellular matrix assembly Monocrotaline results in increased positive regulation of extracellular matrix assembly 1: Rattus norvegicus Pulmonary Artery 1 gene: TGFB1 1
33. Monocrotaline positive regulation of collagen biosynthetic process Monocrotaline results in increased positive regulation of collagen biosynthetic process 1: Rattus norvegicus Pulmonary Artery
5 genes: CCL2 | IL18 | SERPINE1 | TGFB1 | VIM
1
34. Monocrotaline blood coagulation, fibrin clot formation Lipopolysaccharides [Monocrotaline co-treated with Lipopolysaccharides] results in increased blood coagulation, fibrin clot formation 1: Mus musculus Liver   1
35. Monocrotaline lipoprotein oxidation Lipopolysaccharides [Monocrotaline co-treated with Lipopolysaccharides] results in increased lipoprotein oxidation 1: Mus musculus Liver   1
36. Monocrotaline lipoprotein oxidation Lipopolysaccharides [Monocrotaline co-treated with Lipopolysaccharides] results in increased lipoprotein oxidation 1: Mus musculus Plasma   1
37. Monocrotaline lipoprotein oxidation Lipopolysaccharides | malondialdehyde-low density lipoprotein, mouse [[Monocrotaline co-treated with Lipopolysaccharides] results in increased lipoprotein oxidation] which results in increased abundance of malondialdehyde-low density lipoprotein, mouse 1: Mus musculus Liver   1
38. Monocrotaline lipoprotein oxidation Lipopolysaccharides | malondialdehyde-low density lipoprotein, mouse [[Monocrotaline co-treated with Lipopolysaccharides] results in increased lipoprotein oxidation] which results in increased abundance of malondialdehyde-low density lipoprotein, mouse 1: Mus musculus Plasma   1
39. Monocrotaline positive regulation of cell proliferation Lipopolysaccharides [Monocrotaline co-treated with Lipopolysaccharides] results in increased positive regulation of cell proliferation 1: Mus musculus Erythrocytes
27 genes: AGT | AKT1 | BCL2L1 | BIRC5 | CCND1 | CTNNB1 | CXCL10 | EDN1 | EDNRA | FASL | FN1 | HTR2A | IL18 | IL1B | IL6 | ITGB1 | LEP | LGALS3 | MDM2 | MIR132 | NOX1 | STAT3 | TGFB1 | TIMP1 | TNC | TNF | VEGFA
1
40. Monocrotaline positive regulation of cellular extravasation Lipopolysaccharides [Monocrotaline co-treated with Lipopolysaccharides] results in increased positive regulation of cellular extravasation 1: Mus musculus Liver | Leukocytes
3 genes: CCL2 | PLVAP | THY1
1
41. Monocrotaline nuclear fragmentation involved in apoptotic nuclear change Lipopolysaccharides [Monocrotaline co-treated with Lipopolysaccharides] results in increased nuclear fragmentation involved in apoptotic nuclear change 1: Mus musculus Liver   1
42. Monocrotaline leukocyte homeostasis Lipopolysaccharides [Monocrotaline co-treated with Lipopolysaccharides] results in decreased leukocyte homeostasis 1: Mus musculus Blood 1 gene: BAX 1
43. Monocrotaline leukocyte homeostasis Lipopolysaccharides | negative regulation of granulocyte differentiation [[Monocrotaline co-treated with Lipopolysaccharides] results in decreased leukocyte homeostasis] which results in increased negative regulation of granulocyte differentiation 1: Mus musculus Blood 1 gene: BAX 1
44. Monocrotaline negative regulation of granulocyte differentiation leukocyte homeostasis | Lipopolysaccharides [[Monocrotaline co-treated with Lipopolysaccharides] results in decreased leukocyte homeostasis] which results in increased negative regulation of granulocyte differentiation 1: Mus musculus Blood   1
45. Monocrotaline leukocyte homeostasis Lipopolysaccharides | negative regulation of lymphocyte differentiation [[Monocrotaline co-treated with Lipopolysaccharides] results in decreased leukocyte homeostasis] which results in increased negative regulation of lymphocyte differentiation 1: Mus musculus Blood 1 gene: BAX 1
46. Monocrotaline negative regulation of lymphocyte differentiation leukocyte homeostasis | Lipopolysaccharides [[Monocrotaline co-treated with Lipopolysaccharides] results in decreased leukocyte homeostasis] which results in increased negative regulation of lymphocyte differentiation 1: Mus musculus Blood   1
47. Monocrotaline leukocyte homeostasis Monocrotaline results in decreased leukocyte homeostasis 1: Mus musculus Blood 1 gene: BAX 1
48. Monocrotaline leukocyte homeostasis negative regulation of lymphocyte differentiation [Monocrotaline results in decreased leukocyte homeostasis] which results in increased negative regulation of lymphocyte differentiation 1: Mus musculus Blood 1 gene: BAX 1
49. Monocrotaline negative regulation of lymphocyte differentiation leukocyte homeostasis [Monocrotaline results in decreased leukocyte homeostasis] which results in increased negative regulation of lymphocyte differentiation 1: Mus musculus Blood   1
50. Monocrotaline leukocyte homeostasis Lipopolysaccharides Lipopolysaccharides promotes the reaction [Monocrotaline results in decreased leukocyte homeostasis] 1: Mus musculus Blood 1 gene: BAX 1
1–50 of 138 results.