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GO Term transporter activity

201–250 of 374 results.
  Phenotype Chemical Co-Mentioned Terms Interaction Organisms Anatomy Inference Network References
201. sodium:potassium-exchanging ATPase activity Lipopolysaccharides Curcumin | Tobacco Smoke Pollution Curcumin inhibits the reaction [[Lipopolysaccharides co-treated with Tobacco Smoke Pollution] results in decreased sodium:potassium-exchanging ATPase activity] 1: Rattus norvegicus Muscle, Skeletal | Mitochondria
4 genes: ATP1A1 | ATP1A2 | ATP1A3 | ATP1B1
1
202. calcium-transporting ATPase activity Lipopolysaccharides Curcumin | Tobacco Smoke Pollution Curcumin inhibits the reaction [[Lipopolysaccharides co-treated with Tobacco Smoke Pollution] results in decreased calcium-transporting ATPase activity] 1: Rattus norvegicus Muscle, Skeletal | Mitochondria
3 genes: ANXA5 | ATP2A2 | ATP2B2
1
203. cytochrome-c oxidase activity Malathion Malathion results in decreased cytochrome-c oxidase activity 1: Rattus norvegicus Muscles | Mitochondria
2 genes: COX1 | COX3
1
204. cytochrome-c oxidase activity mangiferin Methylmercury Compounds mangiferin inhibits the reaction [Methylmercury Compounds results in decreased cytochrome-c oxidase activity] 1: Homo sapiens Hep G2 Cells | Mitochondria   1
205. cytochrome-c oxidase activity mecoprop 2,4-Dichlorophenoxyacetic Acid | Dicamba [2,4-Dichlorophenoxyacetic Acid co-treated with mecoprop co-treated with Dicamba] results in increased cytochrome-c oxidase activity 1: Mya arenaria Tissues 1 gene: COX7C 1
206. sodium:potassium-exchanging ATPase activity methylmercuric chloride methylmercuric chloride results in decreased sodium:potassium-exchanging ATPase activity 1: Rattus norvegicus Cerebral Cortex
6 genes: ATP1A2 | ATP1B1 | ATP1B2 | ATP1B3 | CATP-4 | MYH9
1
207. calcium-transporting ATPase activity methylmercuric chloride methylmercuric chloride results in decreased calcium-transporting ATPase activity 1: Rattus norvegicus Cerebral Cortex
3 genes: ATP2A2 | ATP2B1 | ATP2B2
1
208. sodium:potassium-exchanging ATPase activity methylmercuric chloride Thioctic Acid Thioctic Acid inhibits the reaction [methylmercuric chloride results in decreased sodium:potassium-exchanging ATPase activity] 1: Rattus norvegicus Cerebral Cortex
6 genes: ATP1A2 | ATP1B1 | ATP1B2 | ATP1B3 | CATP-4 | MYH9
1
209. calcium-transporting ATPase activity methylmercuric chloride Thioctic Acid Thioctic Acid inhibits the reaction [methylmercuric chloride results in decreased calcium-transporting ATPase activity] 1: Rattus norvegicus Cerebral Cortex
3 genes: ATP2A2 | ATP2B1 | ATP2B2
1
210. sodium:potassium-exchanging ATPase activity Methylmercury Compounds Methylmercury Compounds results in decreased sodium:potassium-exchanging ATPase activity 1: Rattus norvegicus Brain   1
211. cytochrome-c oxidase activity Methylmercury Compounds Methylmercury Compounds results in decreased cytochrome-c oxidase activity 1: Mus musculus Cerebral Cortex | Mitochondria
4 genes: COX1 | COX5A | COX6A2 | COX6C
1
212. cytochrome-c oxidase activity Methylmercury Compounds Sodium Selenite Sodium Selenite affects the reaction [Methylmercury Compounds results in decreased cytochrome-c oxidase activity] 1: Mus musculus Cerebral Cortex | Mitochondria
4 genes: COX1 | COX5A | COX6A2 | COX6C
1
213. cytochrome-c oxidase activity Methylmercury Compounds Methylmercury Compounds results in decreased cytochrome-c oxidase activity 1: Homo sapiens Hep G2 Cells | Mitochondria
4 genes: COX1 | COX5A | COX6A2 | COX6C
1
214. cytochrome-c oxidase activity Methylmercury Compounds mangiferin mangiferin inhibits the reaction [Methylmercury Compounds results in decreased cytochrome-c oxidase activity] 1: Homo sapiens Hep G2 Cells | Mitochondria
4 genes: COX1 | COX5A | COX6A2 | COX6C
1
215. cytochrome-c oxidase activity 1-Methyl-4-phenylpyridinium 1-Methyl-4-phenylpyridinium results in decreased cytochrome-c oxidase activity 1: Rattus norvegicus Corpus Striatum | Mitochondria
7 genes: COX1 | COX2 | COX3 | COX4I1 | COX4I2 | COX6C | COX7A1
1
216. cytochrome-c oxidase activity 1-Methyl-4-phenylpyridinium Copper Sulfate Copper Sulfate inhibits the reaction [1-Methyl-4-phenylpyridinium results in decreased cytochrome-c oxidase activity] 1: Rattus norvegicus Corpus Striatum | Mitochondria
7 genes: COX1 | COX2 | COX3 | COX4I1 | COX4I2 | COX6C | COX7A1
1
217. calcium-transporting ATPase activity miltefosine miltefosine results in decreased calcium-transporting ATPase activity 1: Rattus norvegicus Leukocytes | Membranes   1
218. delayed rectifier potassium channel activity mitragynine mitragynine affects delayed rectifier potassium channel activity 1: Homo sapiens Myocytes, Cardiac 1 gene: KCNH2 1
219. gap junction channel activity monolaurin monolaurin results in decreased gap junction channel activity 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line   1
220. cytochrome-c oxidase activity morin Acetaminophen morin inhibits the reaction [Acetaminophen results in decreased cytochrome-c oxidase activity] 1: Rattus norvegicus Kidney Tubules, Proximal | Cell Line   1
221. proton-transporting ATPase activity, rotational mechanism morin morin results in decreased proton-transporting ATPase activity, rotational mechanism 1: Rattus norvegicus Brain | Mitochondria   1
222. voltage-gated potassium channel activity N-(2-(4-bromocinnamylamino)ethyl)-5-isoquinolinesulfonamide Glucose | KMUP 1 N-(2-(4-bromocinnamylamino)ethyl)-5-isoquinolinesulfonamide inhibits the reaction [KMUP 1 inhibits the reaction [Glucose results in increased voltage-gated potassium channel activity]] 1: Rattus norvegicus Pancreas | Insulin-Secreting Cells | Cells, Cultured
4 genes: KCNE1 | KCNH2 | KCNQ1 | SNAP25
1
223. cytochrome-c oxidase activity Sodium Azide Sodium Azide results in decreased cytochrome-c oxidase activity 1: Homo sapiens Hep G2 Cells | Mitochondria
2 genes: COX2 | COX3
1
224. cytochrome-c oxidase activity naringin sodium arsenite naringin inhibits the reaction [sodium arsenite results in decreased cytochrome-c oxidase activity] 1: Rattus norvegicus Heart | Mitochondria   1
225. calcium-activated potassium channel activity N-hydroxy-N'-(4-butyl-2-methylphenyl)formamidine N-hydroxy-N'-(4-butyl-2-methylphenyl)formamidine affects calcium-activated potassium channel activity 1: Rattus norvegicus Brain | Astrocytes | Cells, Cultured   1
226. sodium:potassium-exchanging ATPase activity nickel carbonyl nickel carbonyl results in decreased sodium:potassium-exchanging ATPase activity 1: Rattus norvegicus Lung 1 gene: ATP1A1 1
227. cytochrome-c oxidase activity Nitrites Oxygen [Nitrites co-treated with Oxygen deficiency] results in increased cytochrome-c oxidase activity 1: Rattus norvegicus Aorta | Myocytes, Smooth Muscle | Cells, Cultured   1
228. proton-transporting ATPase activity, rotational mechanism Oligomycins Oligomycins results in decreased proton-transporting ATPase activity, rotational mechanism 1: Rattus norvegicus Brain | Mitochondria   1
229. voltage-gated potassium channel activity oxotremorine M oxotremorine M results in decreased voltage-gated potassium channel activity 1: Rattus norvegicus Superior Cervical Ganglion | Neurons   1
230. voltage-gated potassium channel activity oxotremorine M Valproic Acid Valproic Acid inhibits the reaction [oxotremorine M results in decreased voltage-gated potassium channel activity] 1: Rattus norvegicus Superior Cervical Ganglion | Neurons   1
231. voltage-gated potassium channel activity oxotremorine M AKAP5 AKAP5 protein affects the reaction [oxotremorine M results in decreased voltage-gated potassium channel activity] 1: Rattus norvegicus Superior Cervical Ganglion | Neurons   1
232. voltage-gated potassium channel activity oxotremorine M AKAP5 AKAP5 protein affects the reaction [AKAP5 protein affects the reaction [oxotremorine M results in decreased voltage-gated potassium channel activity]] 1: Homo sapiens Superior Cervical Ganglion | Neurons   1
233. cytochrome-c oxidase activity Oxygen Nitrites [Nitrites co-treated with Oxygen deficiency] results in increased cytochrome-c oxidase activity 1: Rattus norvegicus Aorta | Myocytes, Smooth Muscle | Cells, Cultured
7 genes: COX1 | COX10 | COX4I1 | COX5A | COX5B | COX7A1 | NDUFA4
1
234. delayed rectifier potassium channel activity paynantheine paynantheine affects delayed rectifier potassium channel activity 1: Homo sapiens Myocytes, Cardiac   1
235. gap junction channel activity Pentachlorophenol Pentachlorophenol results in decreased gap junction channel activity 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line 1 gene: GJB1 1
236. gap junction hemi-channel activity Peptides GJB1 [Peptides results in decreased activity of GJB1 protein] which results in decreased gap junction hemi-channel activity 1: Rattus norvegicus Hepatocytes | Cells, Cultured   1
237. gap junction hemi-channel activity Peptides GJA1 [Peptides results in decreased activity of GJA1 protein] which results in decreased gap junction hemi-channel activity 1: Rattus norvegicus Hepatocytes | Cells, Cultured   1
238. gap junction hemi-channel activity Peptides Peptides results in decreased gap junction hemi-channel activity 1: Rattus norvegicus Hepatocytes | Cells, Cultured   1
239. gap junction hemi-channel activity Peptides Adenosine Triphosphate [Peptides results in decreased gap junction hemi-channel activity] which results in decreased export of Adenosine Triphosphate 1: Rattus norvegicus Hepatocytes | Cells, Cultured   1
240. gap junction channel activity perfluorodecanoic acid perfluorodecanoic acid results in decreased gap junction channel activity 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line   1
241. gap junction channel activity perfluorodecanoic acid tricyclodecane-9-yl-xanthogenate tricyclodecane-9-yl-xanthogenate inhibits the reaction [perfluorodecanoic acid results in decreased gap junction channel activity] 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line   1
242. gap junction channel activity perfluorooctane sulfonic acid perfluorooctane sulfonic acid results in decreased gap junction channel activity 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line 1 gene: GJA1 1
243. gap junction channel activity perfluorooctanoic acid perfluorooctanoic acid results in decreased gap junction channel activity 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line 1 gene: GJA1 1
244. gap junction channel activity perfluorooctanoic acid tricyclodecane-9-yl-xanthogenate tricyclodecane-9-yl-xanthogenate inhibits the reaction [perfluorooctanoic acid results in decreased gap junction channel activity] 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line 1 gene: GJA1 1
245. gap junction channel activity perfluorooctanoic acid U 0126 U 0126 inhibits the reaction [perfluorooctanoic acid results in decreased gap junction channel activity] 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line 1 gene: GJA1 1
246. gap junction channel activity perfluorooctanoic acid Resveratrol Resveratrol inhibits the reaction [perfluorooctanoic acid results in decreased gap junction channel activity] 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line 1 gene: GJA1 1
247. cytochrome-c oxidase activity periodate-oxidized adenosine Phenylephrine periodate-oxidized adenosine inhibits the reaction [Phenylephrine results in decreased cytochrome-c oxidase activity] 1: Rattus norvegicus Myocytes, Cardiac | Cells, Cultured
2 genes: COX11 | COX4I1
1
248. cytochrome-c oxidase activity Pesticides Pesticides results in increased cytochrome-c oxidase activity 1: Homo sapiens Placenta   1
249. gap junction channel activity phenanthrene phenanthrene results in decreased gap junction channel activity 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line 1 gene: GJB1 1
250. gap junction channel activity phenanthrene tricyclodecane-9-yl-xanthogenate tricyclodecane-9-yl-xanthogenate inhibits the reaction [phenanthrene results in decreased gap junction channel activity] 1: Rattus norvegicus Liver | Epithelial Cells | Cell Line 1 gene: GJB1 1
201–250 of 374 results.