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Event: 1614
Key Event Title
Decrease, androgen receptor activation
Short name
Biological Context
Level of Biological Organization |
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Tissue |
Organ term
Key Event Components
Key Event Overview
AOPs Including This Key Event
AOP Name | Role of event in AOP | Point of Contact | Author Status | OECD Status |
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Cyp17A1 inhibition leads to undescended testes in mammals | KeyEvent | Evgeniia Kazymova (send email) | Open for citation & comment | |
5α-reductase inhibition leading to short AGD | KeyEvent | Allie Always (send email) | Under development: Not open for comment. Do not cite | Under Development |
AR antagonism leading to short AGD | KeyEvent | Evgeniia Kazymova (send email) | Under development: Not open for comment. Do not cite | Under Development |
Decreased testosterone synthesis leading to short AGD | KeyEvent | Cataia Ives (send email) | Under development: Not open for comment. Do not cite | Under Development |
AR antagonism leading to NR | KeyEvent | Evgeniia Kazymova (send email) | Under development: Not open for comment. Do not cite | Under Development |
Androgen receptor antagonism and testicular cancer | KeyEvent | Brendan Ferreri-Hanberry (send email) | Under development: Not open for comment. Do not cite | |
AR antagonism leading to hypospadias | KeyEvent | Brendan Ferreri-Hanberry (send email) | Under development: Not open for comment. Do not cite | |
AR antagonism leading to decreased fertility | KeyEvent | Cataia Ives (send email) | Under development: Not open for comment. Do not cite | Under Development |
Taxonomic Applicability
Term | Scientific Term | Evidence | Link |
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mammals | mammals | High | NCBI |
Life Stages
Life stage | Evidence |
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During development and at adulthood | High |
Sex Applicability
Term | Evidence |
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Mixed | High |
Key Event Description
This KE refers to decreased activation of the androgen receptor (AR) as occurring in complex biological systems such as tissues and organs in vivo. It is thus considered distinct from KEs describing either blocking of AR or decreased androgen synthesis.
The AR is a nuclear transcription factor with canonical AR activation regulated by the binding of the androgens such as testosterone or dihydrotestosterone (DHT). Thus, AR activity can be decreased by reduced levels of steroidal ligands (testosterone, DHT) or the presence of compounds interfering with ligand binding to the receptor (Davey & Grossmann, 2016; Gao et al., 2005).
In the inactive state, AR is sequestered in the cytoplasm of cells by molecular chaperones. In the classical (genomic) AR signaling pathway, AR activation causes dissociation of the chaperones, AR dimerization and translocation to the nucleus to modulate gene expression. AR binds to the androgen response element (ARE) (Davey & Grossmann, 2016; Gao et al., 2005). Notably, for transcriptional regulation the AR is closely associated with other co-factors that may differ between cells, tissues and life stages. In this way, the functional consequence of AR activation is cell- and tissue-specific. This dependency on co-factors such as the SRC proteins also means that stressors affecting recruitment of co-activators to AR can result in decreased AR activity (Heinlein & Chang, 2002).
Ligand-bound AR may also associate with cytoplasmic and membrane-bound proteins to initiate cytoplasmic signaling pathways with other functions than the nuclear pathway. Non-genomic AR signaling includes association with Src kinase to activate MAPK/ERK signaling and activation of the PI3K/Akt pathway. Decreased AR activity may therefore be a decrease in the genomic and/or non-genomic AR signaling pathways (Leung & Sadar, 2017).
How It Is Measured or Detected
This KE specifically focuses on decreased in vivo activation, with most methods that can be used to measure AR activity carried out in vitro. They provide indirect information about the KE and are described in lower tier MIE/KEs (see for example MIE/KE-26 for AR antagonism, KE-1690 for decreased T levels and KE-1613 for decreased dihydrotestosterone levels). In this way, this KE is a placeholder for tissue-specific responses to AR activation or inactivation that will depend on the adverse outcome (AO) for which it is included.
In fish, The Rapid Androgen Disruption Activity Reporter (RADAR) assay included in OECD test guideline no. 251 can be used to measure genomic AR activity (OECD, 2022). Employing a spg1-gfp construct under control of the AR-binding promoter spiggin1 in medaka fish embryos, any stressor activating or inhibiting the androgen axis will be detected. This includes for instance stressors that agonize or antagonize AR, as well as stressors that modulate androgen synthesis or metabolism. Non-genomic AR activity cannot be detected by the RADAR assay (OECD, 2022). Similar assays may in the future be developed to measure AR activity in mammalian organisms.
Domain of Applicability
This KE is considered broadly applicable across mammalian taxa as all mammals express the AR in numerous cells and tissues where it regulates gene transcription required for developmental processes and functions. It is, however, acknowledged that this KE most likely has a much broader domain of applicability extending to non-mammalian vertebrates. AOP developers are encouraged to add additional relevant knowledge to expand on the applicability to also include other vertebrates.
References
Davey, R. A., & Grossmann, M. (2016). Androgen Receptor Structure, Function and Biology: From Bench to Bedside. The Clinical Biochemist. Reviews, 37(1), 3–15.
Gao, W., Bohl, C. E., & Dalton, J. T. (2005). Chemistry and structural biology of androgen receptor. Chemical Reviews, 105(9), 3352–3370. https://doi.org/10.1021/cr020456u
Heinlein, C. A., & Chang, C. (2002). Androgen Receptor (AR) Coregulators: An Overview. https://academic.oup.com/edrv/article/23/2/175/2424160
Leung, J. K., & Sadar, M. D. (2017). Non-Genomic Actions of the Androgen Receptor in Prostate Cancer. Frontiers in Endocrinology, 8. https://doi.org/10.3389/fendo.2017.00002
OECD (2022). Test No. 251: Rapid Androgen Disruption Activity Reporter (RADAR) assay. Paris: OECD Publishing doi:10.1787/da264d82-en.