| GO ID | GO name | Interaction type | Reference |
|---|---|---|---|
| GO:0000737 | Dna catabolic process, endonucleolytic | Increases phenotype | PMID:28703385 |
| GO:0006750 | Glutathione biosynthetic process | Affects phenotype | PMID:19723100 |
| GO:0006914 | Autophagy | Decreases phenotype | PMID:20417273 |
| GO:0006915 | Apoptotic process | Increases phenotype | PMID:10353256; PMID:10477740; PMID:10490238 |
| GO:0006979 | Response to oxidative stress | Increases phenotype | PMID:12423650 |
| GO:0008217 | Regulation of blood pressure | Decreases phenotype | PMID:9880127 |
| GO:0008219 | Cell death | Increases phenotype | PMID:19059302; PMID:25820916 |
| GO:0008283 | Cell population proliferation | Decreases phenotype | PMID:8951241 |
| GO:0010918 | Positive regulation of mitochondrial membrane potential | Decreases phenotype | PMID:25446858 |
| GO:0010942 | Positive regulation of cell death | Increases phenotype | PMID:25446858; PMID:26598004 |
| GO:0016049 | Cell growth | Decreases phenotype | PMID:29467594 |
| GO:0018158 | Protein oxidation | Increases phenotype | PMID:25446858 |
| GO:0031987 | Locomotion involved in locomotory behavior | Increases phenotype | PMID:34757178 |
| GO:0042403 | Thyroid hormone metabolic process | Affects phenotype | PMID:34757178 |
| GO:0042744 | Hydrogen peroxide catabolic process | Decreases phenotype | PMID:20558743 |
| GO:0042756 | Drinking behavior | Increases phenotype | PMID:31550440 |
| GO:1900182 | Positive regulation of protein localization to nucleus | Increases phenotype | PMID:31162603 |
| GO:1903409 | Reactive oxygen species biosynthetic process | Increases phenotype | PMID:19723100; PMID:25820916 |
| GO:1903428 | Positive regulation of reactive oxygen species biosynthetic process | Increases phenotype | PMID:25446858; PMID:28703385 |
We have built a comprehensive resource which compiles potential endocrine disrupting chemicals (EDCs) based on the observed adverse effects or endocrine-mediated endpoints in published experiments on humans or rodents to support basic research. We are not responsible for any errors or omissions in the published research articles or supporting literature on potential EDCs compiled in this resource. Users are advised to exercise their own judgement on the weight of evidence for potential EDCs compiled in this resource. Importantly, our sole goal to build this resource on potential EDCs is to enable future basic research towards better understanding of the systems-level perturbations upon chemical exposure rather than influencing regulatory advice on chemical use.