Skip navigation

Chemical Hydroxylamines

1–50 of 1,009 results.
  Chemical Phenotype Co-Mentioned Terms Interaction Organisms Anatomy Inference Network References
1. 1,4-bis(4-hydroxyiminomethylpyridinium)butane dibromide neuron death cyclohexyl methylphosphonofluoridate 1,4-bis(4-hydroxyiminomethylpyridinium)butane dibromide inhibits the reaction [cyclohexyl methylphosphonofluoridate results in increased neuron death] 1: Rattus norvegicus   1 gene: ACHE 1
2. 1-(4-hydroxyiminomethylpyridinium)-3-(carbamoylpyridinium) propane dibromide membrane lipid catabolic process Atropine | Malathion [1-(4-hydroxyiminomethylpyridinium)-3-(carbamoylpyridinium) propane dibromide co-treated with Atropine] inhibits the reaction [Malathion results in increased membrane lipid catabolic process] 1: Mus musculus Prefrontal Cortex   1
3. 3,4-dihydroxybenzohydroxamic acid nitric oxide biosynthetic process Lipopolysaccharides 3,4-dihydroxybenzohydroxamic acid inhibits the reaction [Lipopolysaccharides results in increased nitric oxide biosynthetic process] 1: Mus musculus Macrophages | Cell Line, Transformed
2 genes: AKT1 | NOS2
1
4. 3,4-dihydroxybenzohydroxamic acid reactive oxygen species metabolic process Lipopolysaccharides 3,4-dihydroxybenzohydroxamic acid inhibits the reaction [Lipopolysaccharides results in increased reactive oxygen species metabolic process] 1: Mus musculus Macrophages | Cell Line, Transformed
3 genes: CAT | SOD1 | SOD2
1
5. 3,4-dihydroxybenzohydroxamic acid reactive oxygen species metabolic process Tetradecanoylphorbol Acetate 3,4-dihydroxybenzohydroxamic acid inhibits the reaction [Tetradecanoylphorbol Acetate results in increased reactive oxygen species metabolic process] 1: Mus musculus Macrophages | Cell Line, Transformed
3 genes: CAT | SOD1 | SOD2
1
6. 3,4-dihydroxybenzohydroxamic acid reactive oxygen species metabolic process Buthionine Sulfoximine 3,4-dihydroxybenzohydroxamic acid inhibits the reaction [Buthionine Sulfoximine results in increased reactive oxygen species metabolic process] 1: Mus musculus Macrophages | Cell Line, Transformed
3 genes: CAT | SOD1 | SOD2
1
7. 3,4-dihydroxybenzohydroxamic acid reactive oxygen species metabolic process Buthionine Sulfoximine | Tetradecanoylphorbol Acetate 3,4-dihydroxybenzohydroxamic acid inhibits the reaction [[Buthionine Sulfoximine co-treated with Tetradecanoylphorbol Acetate] results in increased reactive oxygen species metabolic process] 1: Mus musculus Macrophages | Cell Line, Transformed
3 genes: CAT | SOD1 | SOD2
1
8. 6-(4-chlorophenyl)imidazo(2,1-b)(1,3)thiazole-5-carbaldehyde O-(3,4-dichlorobenzyl)oxime DNA biosynthetic process HGF | IL6 | TGFA 6-(4-chlorophenyl)imidazo(2,1-b)(1,3)thiazole-5-carbaldehyde O-(3,4-dichlorobenzyl)oxime promotes the reaction [[IL6 protein co-treated with HGF protein co-treated with TGFA protein] results in increased DNA biosynthetic process] 1: Homo sapiens Hepatocytes | Cells, Cultured   1
9. 6-(4-chlorophenylsulfanyl)-2,4-hexadienoic acid hydroxyamide histone H3-K9 acetylation 6-(4-chlorophenylsulfanyl)-2,4-hexadienoic acid hydroxyamide results in increased histone H3-K9 acetylation 1: Homo sapiens Bone and Bones | Cell Line, Tumor   1
10. 6,7-dichloro-1H-indole-2,3-dione 3-oxime positive regulation of vasoconstriction 4-(4-(3-adamantan-1-ylureido)cyclohexyloxy)benzoic acid | Dietary Fats | Serotonin [4-(4-(3-adamantan-1-ylureido)cyclohexyloxy)benzoic acid co-treated with Dietary Fats] inhibits the reaction [6,7-dichloro-1H-indole-2,3-dione 3-oxime inhibits the reaction [Serotonin results in increased positive regulation of vasoconstriction]] 1: Mus musculus Coronary Vessels   1
11. 6,7-dichloro-1H-indole-2,3-dione 3-oxime positive regulation of vasoconstriction Serotonin 6,7-dichloro-1H-indole-2,3-dione 3-oxime inhibits the reaction [Serotonin results in increased positive regulation of vasoconstriction] 1: Mus musculus Coronary Vessels   1
12. 6-bromoindirubin-3'-oxime cell death GSK3B | Sorafenib [6-bromoindirubin-3'-oxime results in decreased activity of GSK3B protein] inhibits the reaction [Sorafenib results in increased cell death] 1: Homo sapiens Cell Line, Tumor   1
13. 6-bromoindirubin-3'-oxime positive regulation of canonical Wnt signaling pathway 6-bromoindirubin-3'-oxime results in increased positive regulation of canonical Wnt signaling pathway 1: Homo sapiens Kidney | Cell Line, Tumor
3 genes: DDX3X | LGR5 | POU5F1
1
14. 6-bromoindirubin-3'-oxime positive regulation of extrinsic apoptotic signaling pathway Paraquat 6-bromoindirubin-3'-oxime promotes the reaction [Paraquat results in increased positive regulation of extrinsic apoptotic signaling pathway] 1: Homo sapiens Lung | Cell Line, Tumor 1 gene: CASP8 1
15. A 967079 positive regulation of cell death TRPA1 [TRPA1 protein results in increased susceptibility to A 967079] which results in decreased positive regulation of cell death 1: Homo sapiens HEK293 Cells 1 gene: IL1B 1
16. A 967079 positive regulation of cytosolic calcium ion concentration zinc chloride A 967079 inhibits the reaction [zinc chloride results in increased positive regulation of cytosolic calcium ion concentration] 1: Homo sapiens HEK293 Cells 1 gene: IL1B 1
17. A 967079 positive regulation of cytosolic calcium ion concentration zinc chloride A 967079 inhibits the reaction [zinc chloride results in increased positive regulation of cytosolic calcium ion concentration] 1: Homo sapiens Lung | Cell Line, Tumor 1 gene: IL1B 1
18. A 967079 positive regulation of cytosolic calcium ion concentration allyl isothiocyanate A 967079 inhibits the reaction [allyl isothiocyanate results in increased positive regulation of cytosolic calcium ion concentration] 1: Homo sapiens HEK293 Cells 1 gene: IL1B 1
19. A 967079 positive regulation of cytosolic calcium ion concentration allyl isothiocyanate A 967079 inhibits the reaction [allyl isothiocyanate results in increased positive regulation of cytosolic calcium ion concentration] 1: Homo sapiens Lung | Cell Line, Tumor 1 gene: IL1B 1
20. abexinostat apoptotic process abexinostat results in increased apoptotic process 1: Homo sapiens Lymphocytes | Cell Line, Tumor
6 genes: CASP3 | CASP8 | CASP9 | HMOX1 | NFKB1 | PARP1
1
21. abexinostat cell cycle abexinostat results in decreased cell cycle 1: Homo sapiens Lymphocytes | Cell Line, Tumor 1 gene: CDKN1A 1
22. abexinostat response to oxidative stress abexinostat results in increased response to oxidative stress 1: Homo sapiens Lymphocytes | Cell Line, Tumor
4 genes: HMOX1 | HMOX2 | NFKB1 | TXN2
1
23. abexinostat apoptotic process abexinostat results in increased apoptotic process 1: Homo sapiens Lymphocytes | Tumor Cells, Cultured
6 genes: CASP3 | CASP8 | CASP9 | HMOX1 | NFKB1 | PARP1
1
24. abexinostat apoptotic process Bortezomib Bortezomib promotes the reaction [abexinostat results in increased apoptotic process] 1: Homo sapiens Lymphocytes | Cell Line, Tumor
6 genes: CASP3 | CASP8 | CASP9 | HMOX1 | NFKB1 | PARP1
1
25. abexinostat response to oxidative stress Bortezomib Bortezomib promotes the reaction [abexinostat results in increased response to oxidative stress] 1: Homo sapiens Lymphocytes | Cell Line, Tumor
4 genes: HMOX1 | HMOX2 | NFKB1 | TXN2
1
26. abexinostat apoptotic process Bortezomib Bortezomib promotes the reaction [abexinostat results in increased apoptotic process] 1: Homo sapiens Lymphocytes | Tumor Cells, Cultured
6 genes: CASP3 | CASP8 | CASP9 | HMOX1 | NFKB1 | PARP1
1
27. abexinostat regulation of mitochondrial membrane potential abexinostat results in decreased regulation of mitochondrial membrane potential 1: Homo sapiens Lymphocytes | Cell Line, Tumor   1
28. abexinostat regulation of mitochondrial membrane potential Bortezomib Bortezomib promotes the reaction [abexinostat results in decreased regulation of mitochondrial membrane potential] 1: Homo sapiens Lymphocytes | Cell Line, Tumor   1
29. abexinostat apoptotic process Bortezomib | quinoline-val-asp(OMe)-CH2-OPH quinoline-val-asp(OMe)-CH2-OPH inhibits the reaction [Bortezomib promotes the reaction [abexinostat results in increased apoptotic process]] 1: Homo sapiens Lymphocytes | Cell Line, Tumor
6 genes: CASP3 | CASP8 | CASP9 | HMOX1 | NFKB1 | PARP1
1
30. acetohydroxamic acid cell death acetohydroxamic acid results in increased cell death 1: Homo sapiens K562 Cells   1
31. Aminooxyacetic Acid cell death Cacodylic Acid Aminooxyacetic Acid inhibits the reaction [Cacodylic Acid results in increased cell death] 1: Rattus norvegicus Cell Line | Liver | Epithelial Cells   1
32. Aminooxyacetic Acid response to oxidative stress S-(1,2-dichlorovinyl)cysteine Aminooxyacetic Acid inhibits the reaction [S-(1,2-dichlorovinyl)cysteine results in increased response to oxidative stress] 1: Rattus norvegicus Kidney Tubules, Proximal | Cells, Cultured
2 genes: GSR | TAT
1
33. Aminooxyacetic Acid cell death S-(1,2-dichlorovinyl)cysteine Aminooxyacetic Acid inhibits the reaction [S-(1,2-dichlorovinyl)cysteine results in increased cell death] 1: Rattus norvegicus Kidney Tubules, Proximal | Cells, Cultured   1
34. Aminooxyacetic Acid regulation of mitochondrial membrane potential Glucose | GPD2 [GPD2 mutant form co-treated with Aminooxyacetic Acid] inhibits the reaction [Glucose results in increased regulation of mitochondrial membrane potential] 1: Mus musculus Islets of Langerhans   1
35. Aminooxyacetic Acid ion transport Glucose | GPD2 [GPD2 mutant form co-treated with Aminooxyacetic Acid] inhibits the reaction [Glucose results in increased ion transport] 1: Mus musculus Islets of Langerhans | Mitochondria   1
36. Aminooxyacetic Acid histone H3 acetylation selenomethylselenocysteine [Aminooxyacetic Acid results in decreased metabolism of selenomethylselenocysteine] which results in decreased histone H3 acetylation 1: Homo sapiens HCT116 Cells   1
37. Aminooxyacetic Acid glutamate biosynthetic process Carbon Tetrachloride | Ketoglutaric Acids Aminooxyacetic Acid affects the reaction [Ketoglutaric Acids promotes the reaction [Carbon Tetrachloride results in increased glutamate biosynthetic process]] 1: Mus musculus Plasma 1 gene: GLUD1 1
38. asoxime chloride organophosphate catabolic process ACHE [asoxime chloride results in increased activity of ACHE protein] which results in increased organophosphate catabolic process 1: Homo sapiens Blood   1
39. asoxime chloride organophosphate catabolic process BCHE [asoxime chloride results in increased activity of BCHE protein] which results in increased organophosphate catabolic process 1: Homo sapiens Blood   1
40. asoxime chloride organophosphate catabolic process ACHE | VX [[asoxime chloride results in increased activity of ACHE protein] which results in increased organophosphate catabolic process] which results in decreased abundance of VX 1: Homo sapiens Blood   1
41. asoxime chloride organophosphate catabolic process BCHE | VX [[asoxime chloride results in increased activity of BCHE protein] which results in increased organophosphate catabolic process] which results in decreased abundance of VX 1: Homo sapiens Blood   1
42. asoxime chloride positive regulation of response to drug asoxime chloride results in increased positive regulation of response to drug 1: Cavia porcellus Tissues   1
43. asoxime chloride positive regulation of response to drug Atropine [asoxime chloride results in increased positive regulation of response to drug] which results in increased susceptibility to Atropine 1: Cavia porcellus Tissues   1
44. asoxime chloride neuron death Atropine | cyclohexyl methylphosphonofluoridate [asoxime chloride co-treated with Atropine] inhibits the reaction [cyclohexyl methylphosphonofluoridate results in increased neuron death] 1: Rattus norvegicus   1 gene: ACHE 1
45. asoxime chloride platelet aggregation Arachidonic Acid asoxime chloride inhibits the reaction [Arachidonic Acid results in increased platelet aggregation] 1: Homo sapiens Plasma   1
46. asoxime chloride platelet aggregation Adenosine Diphosphate asoxime chloride inhibits the reaction [Adenosine Diphosphate results in increased platelet aggregation] 1: Homo sapiens Plasma   1
47. belinostat apoptotic process belinostat results in increased apoptotic process 1: Homo sapiens B-Lymphocytes | Tumor Cells, Cultured
43 genes: ABL1 | AKT1 | ARRB1 | AVEN | BCL2 | BCL2L11 | BCLAF1 | BIRC5 | CASP3 | CASP8 | CASP9 | CCKBR | CDK1 | CDKN2A | DCC | EAF2 | EPB41L3 | EPHA7 | FOXO1 | GADD45A | GREM1 | IFNG | MAP3K5 | NFKB1 | NFKBIA | PARP1 | PAX3 | PCSK9 | PEG10 | PHLDA1 | PHLDA2 | PIM1 | PPP1R15A | RHOB | RNF144B | SERPINB9 | SPINK2 | TFAP2B | TP53 | TPX2 | TRIB3 | TRP53 | ZMAT3
1
48. belinostat apoptotic process Bortezomib Bortezomib promotes the reaction [belinostat results in increased apoptotic process] 1: Homo sapiens B-Lymphocytes | Tumor Cells, Cultured
43 genes: ABL1 | AKT1 | ARRB1 | AVEN | BCL2 | BCL2L11 | BCLAF1 | BIRC5 | CASP3 | CASP8 | CASP9 | CCKBR | CDK1 | CDKN2A | DCC | EAF2 | EPB41L3 | EPHA7 | FOXO1 | GADD45A | GREM1 | IFNG | MAP3K5 | NFKB1 | NFKBIA | PARP1 | PAX3 | PCSK9 | PEG10 | PHLDA1 | PHLDA2 | PIM1 | PPP1R15A | RHOB | RNF144B | SERPINB9 | SPINK2 | TFAP2B | TP53 | TPX2 | TRIB3 | TRP53 | ZMAT3
1
49. belinostat apoptotic process belinostat results in increased apoptotic process 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor
43 genes: ABL1 | AKT1 | ARRB1 | AVEN | BCL2 | BCL2L11 | BCLAF1 | BIRC5 | CASP3 | CASP8 | CASP9 | CCKBR | CDK1 | CDKN2A | DCC | EAF2 | EPB41L3 | EPHA7 | FOXO1 | GADD45A | GREM1 | IFNG | MAP3K5 | NFKB1 | NFKBIA | PARP1 | PAX3 | PCSK9 | PEG10 | PHLDA1 | PHLDA2 | PIM1 | PPP1R15A | RHOB | RNF144B | SERPINB9 | SPINK2 | TFAP2B | TP53 | TPX2 | TRIB3 | TRP53 | ZMAT3
1
50. belinostat apoptotic process Bortezomib Bortezomib promotes the reaction [belinostat results in increased apoptotic process] 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor
43 genes: ABL1 | AKT1 | ARRB1 | AVEN | BCL2 | BCL2L11 | BCLAF1 | BIRC5 | CASP3 | CASP8 | CASP9 | CCKBR | CDK1 | CDKN2A | DCC | EAF2 | EPB41L3 | EPHA7 | FOXO1 | GADD45A | GREM1 | IFNG | MAP3K5 | NFKB1 | NFKBIA | PARP1 | PAX3 | PCSK9 | PEG10 | PHLDA1 | PHLDA2 | PIM1 | PPP1R15A | RHOB | RNF144B | SERPINB9 | SPINK2 | TFAP2B | TP53 | TPX2 | TRIB3 | TRP53 | ZMAT3
1
1–50 of 1,009 results.