| GO ID | GO name | Interaction type | Reference |
|---|---|---|---|
| GO:0001510 | Rna methylation | Decreases phenotype | PMID:31146095 |
| GO:0001541 | Ovarian follicle development | Decreases phenotype | PMID:36642194 |
| GO:0006306 | Dna methylation | Affects phenotype | PMID:30207508 |
| GO:0006355 | Regulation of dna-templated transcription | Increases phenotype | PMID:25853433; PMID:32827888 |
| GO:0006805 | Xenobiotic metabolic process | Increases phenotype | PMID:29162470 |
| GO:0006915 | Apoptotic process | Increases phenotype | PMID:23555832 |
| GO:0007283 | Spermatogenesis | Decreases phenotype | PMID:32827888 |
| GO:0008209 | Androgen metabolic process | Decreases phenotype | PMID:25929820 |
| GO:0008210 | Estrogen metabolic process | Affects phenotype | PMID:36642194 |
| GO:0008283 | Cell population proliferation | Decreases phenotype | PMID:17599374 |
| GO:0008284 | Positive regulation of cell population proliferation | Increases phenotype | PMID:25324206 |
| GO:0008584 | Male gonad development | Decreases phenotype | PMID:34182078 |
| GO:0010424 | Dna methylation on cytosine within a cg sequence | Affects phenotype | PMID:31079544 |
| GO:0030262 | Apoptotic nuclear changes | Increases phenotype | PMID:31152826 |
| GO:0031324 | Negative regulation of cellular metabolic process | Increases phenotype | PMID:35413382 |
| GO:0032502 | Developmental process | Affects phenotype | PMID:34182078 |
| GO:0032776 | Dna methylation on cytosine | Affects phenotype | PMID:31682807 |
| GO:0034587 | Pirna processing | Increases phenotype | PMID:30207508 |
| GO:0040015 | Negative regulation of multicellular organism growth | Increases phenotype | PMID:31682807 |
| GO:0040018 | Positive regulation of multicellular organism growth | Increases phenotype | PMID:29535025 |
| GO:0040029 | Epigenetic regulation of gene expression | Affects phenotype | PMID:26677731; PMID:30207508 |
| GO:0042307 | Positive regulation of protein import into nucleus | Increases phenotype | PMID:27684650 |
| GO:0044030 | Regulation of dna methylation | Affects phenotype | PMID:25853433; PMID:26677731 |
| GO:0044237 | Cellular metabolic process | Increases phenotype | PMID:35595151 |
| GO:0044553 | Modulation of biological quality in another organism | Affects phenotype | PMID:32827888 |
| GO:0046621 | Negative regulation of organ growth | Increases phenotype | PMID:32827888 |
| GO:0048513 | Animal organ development | Decreases phenotype | PMID:34182078 |
| GO:0050916 | Sensory perception of sweet taste | Affects phenotype | PMID:23410115 |
| GO:0060765 | Regulation of androgen receptor signaling pathway | Affects phenotype | PMID:25324206 |
| GO:0070374 | Positive regulation of erk1 and erk2 cascade | Increases phenotype | PMID:27413106 |
| GO:0071578 | Zinc ion import across plasma membrane | Increases phenotype | PMID:31152826 |
| GO:0090030 | Regulation of steroid hormone biosynthetic process | Affects phenotype | PMID:23558297 |
| GO:0090727 | Positive regulation of brood size | Increases phenotype | PMID:29535025 |
| GO:0140042 | Lipid droplet formation | Increases phenotype | PMID:37046073 |
| GO:1900745 | Positive regulation of p38mapk cascade | Increases phenotype | PMID:27413106; PMID:35413382 |
| GO:1990349 | Gap junction-mediated intercellular transport | Decreases phenotype | PMID:27413106; PMID:35413382 |
| GO:2000225 | Negative regulation of testosterone biosynthetic process | Increases phenotype | PMID:32827888 |
| GO:2000845 | Positive regulation of testosterone secretion | Decreases phenotype | PMID:25929820 |
| GO:2000866 | Positive regulation of estradiol secretion | Increases phenotype | PMID:25929820 |
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.