Steroidogenesis and androgen/estrogen signaling pathways are altered in in vitro matured testicular tissues of prepubertal mice.
Laura MoutardCaroline GoudinCatherine JaegerCéline DuparcEstelle LouisetTony PereiraFrançois FraissinetMarion DelessardJustine SaulnierAurélie Rives-FerailleChristelle DelalandeHervé LefebvreNathalie RivesLudovic DumontChristine RondaninoPublished in: eLife (2023)
Children undergoing cancer treatments are at risk for impaired fertility. Cryopreserved prepubertal testicular biopsies could theoretically be later matured in vitro to produce spermatozoa for assisted reproductive technology. A complete in vitro spermatogenesis has been obtained from mouse prepubertal testicular tissue, although with low efficiency. Steroid hormones are essential for the progression of spermatogenesis, the aim of this study was to investigate steroidogenesis and steroid signaling in organotypic cultures. Histological, RT-qPCR, western blot analyses, and steroid hormone measurements were performed on in vitro cultured mouse prepubertal testicular tissues and age-matched in vivo controls. Despite a conserved density of Leydig cells after 30 days of culture (D30), transcript levels of adult Leydig cells and steroidogenic markers were decreased. Increased amounts of progesterone and estradiol and reduced androstenedione levels were observed at D30, together with decreased transcript levels of steroid metabolizing genes and steroid target genes. hCG was insufficient to facilitate Leydig cell differentiation, restore steroidogenesis, and improve sperm yield. In conclusion, this study reports the failure of adult Leydig cell development and altered steroid production and signaling in tissue cultures. The organotypic culture system will need to be further improved before it can be translated into clinics for childhood cancer survivors.
Keyphrases
- childhood cancer
- induced apoptosis
- germ cell
- young adults
- cell cycle arrest
- genome wide
- signaling pathway
- primary care
- estrogen receptor
- south africa
- squamous cell carcinoma
- cell death
- single cell
- oxidative stress
- pi k akt
- dna methylation
- skeletal muscle
- papillary thyroid
- metabolic syndrome
- adverse drug
- high fat diet induced
- squamous cell
- genome wide identification
- electronic health record
- early life