Introduction: Spinal and bulbar muscular atrophy (SBMA) is an X-linked neuromuscular disease caused by a CAG-repeat expansion in the androgen receptor (AR) gene,translated into an elongated polyglutamine (polyQ) tract in the protein. Androgens trigger ARpolyQ toxicity, thus most potential therapeutic approaches involve androgen reduction or AR negative modulation, with severe endocrine side effects. Objective: A start codon (I-AUGs) controls AR translation, while a second one, (II-AUG) downstream to I-AUG and the CAG repeat, drives translation of the shorter AR isoform (AR-A) lacking the polyQ tract, but preserves all relevant AR functional domains. Here, we studied AR-A behaviour and its effect on ARpolyQ toxicity in SBMA. Methods: We took advantage of both cellular and Drosophila melanogaster SBMA models to asses AR-A behaviour and effect on ARpolyQ aggregation and functions. Results: Comparative expression analyses of AR isoforms revealed that AR-A is predominantly located in the mouse brainstem and spinal cord of the central nervous system, but not in muscle. AR-A retains partial androgenic activity, but does not aggregate. Since ARpolyQ and AR-A can heterodimerize, we tested the effect of AR-A on ARpolyQ behaviour, showing that AR-A has a pro-solubilizing effect on ARpolyQ aggregates and that the heterodimers retain the transcriptional activity. Finally, we tested the effect of AR-A in a fly model of SBMA. Flies expressing AR-A alone showed no signs of external eye degeneration, in contrast to those expressing expanded ARpolyQ. Notably, co-expression of AR-A with ARpolyQ significantly reduced ARpolyQ aggregation and eye degeneration, supporting our hypothesis that AR-A enhances ARpolyQ solubility and mitigates its toxicity in vivo. Conclusions: Altogether, our results demonstrate that an increased expression of AR-A may have a role in protecting against ARpolyQ aggregation and toxicity. These findings suggest that AR-A could represent a promising avenue for developing an alternative therapeutic strategy that warrants further investigation.
The alternative androgen receptor isoform a mitigates toxicity of polyglutamine-elongated mutant androgen receptor in spinal and bulbar muscular atrophy / M. Chierichetti, R. Andreotti, B. Tedesco, V. Ferrari, L. Cornaggia, P. Pramaggiore, M. Cozzi, A. Mohamed, R. Magdalena, M. Piccolella, G. Boarolo, V. Crippa, P. Rusmini, M. Galbiati, C. Rinaldi, E.N. Anderson, U.B. Pandey, M. Pennuto, R. Cristofani, A. Poletti. - In: JOURNAL OF ADVANCED RESEARCH. - ISSN 2090-1232. - (2026). [Epub ahead of print] [10.1016/j.jare.2026.01.051]
The alternative androgen receptor isoform a mitigates toxicity of polyglutamine-elongated mutant androgen receptor in spinal and bulbar muscular atrophy
M. ChierichettiPrimo
;B. Tedesco;V. Ferrari;L. Cornaggia;P. Pramaggiore;M. Cozzi;A. Mohamed;R. Magdalena;M. Piccolella;V. Crippa;P. Rusmini;M. Galbiati;R. CristofaniPenultimo
;A. Poletti
Ultimo
2026
Abstract
Introduction: Spinal and bulbar muscular atrophy (SBMA) is an X-linked neuromuscular disease caused by a CAG-repeat expansion in the androgen receptor (AR) gene,translated into an elongated polyglutamine (polyQ) tract in the protein. Androgens trigger ARpolyQ toxicity, thus most potential therapeutic approaches involve androgen reduction or AR negative modulation, with severe endocrine side effects. Objective: A start codon (I-AUGs) controls AR translation, while a second one, (II-AUG) downstream to I-AUG and the CAG repeat, drives translation of the shorter AR isoform (AR-A) lacking the polyQ tract, but preserves all relevant AR functional domains. Here, we studied AR-A behaviour and its effect on ARpolyQ toxicity in SBMA. Methods: We took advantage of both cellular and Drosophila melanogaster SBMA models to asses AR-A behaviour and effect on ARpolyQ aggregation and functions. Results: Comparative expression analyses of AR isoforms revealed that AR-A is predominantly located in the mouse brainstem and spinal cord of the central nervous system, but not in muscle. AR-A retains partial androgenic activity, but does not aggregate. Since ARpolyQ and AR-A can heterodimerize, we tested the effect of AR-A on ARpolyQ behaviour, showing that AR-A has a pro-solubilizing effect on ARpolyQ aggregates and that the heterodimers retain the transcriptional activity. Finally, we tested the effect of AR-A in a fly model of SBMA. Flies expressing AR-A alone showed no signs of external eye degeneration, in contrast to those expressing expanded ARpolyQ. Notably, co-expression of AR-A with ARpolyQ significantly reduced ARpolyQ aggregation and eye degeneration, supporting our hypothesis that AR-A enhances ARpolyQ solubility and mitigates its toxicity in vivo. Conclusions: Altogether, our results demonstrate that an increased expression of AR-A may have a role in protecting against ARpolyQ aggregation and toxicity. These findings suggest that AR-A could represent a promising avenue for developing an alternative therapeutic strategy that warrants further investigation.
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