Prepubertal ovariectomy confers resilience to stress-induced anxiety in adult female mice

Hormonal contraceptives during adolescence impact the female brain and behavior in a rat model

Millions of people take hormonal contraceptives (HCs), often starting during adolescence when ovarian hormones influence brain and behavioral maturation. However, there is a fundamental lack of information about the neurobehavioral consequences of hormonal alterations via adolescent HC use. To begin addressing this gap, we validated a rodent model of adolescent HC administration and characterized its impact on endocrine, transcriptional, and behavioral endpoints. Cohorts of intact post-pubertal female Sprague-Dawley rats received daily subcutaneous injections of either vehicle or HC [10 μg ethinyl estradiol (EE) + 20 μg levonorgestrel (LNG)] for the duration of adolescence from postnatal day (PND) 35 to PND56. Blood and brain tissue was collected at PND57. Other cohorts received daily injections of vehicle or HC from PND35 until behavioral assays were completed on PND57-64. HC treatment was effective, as vaginal lavage indicated disrupted estrous cycling and ELISA indicated suppressed serum luteinizing hormone in HC-treated rats. Liquid chromatography-mass spectrometry analysis showed EE and LNG in serum and brain as well as diminished serum and brain levels of allopregnanolone and testosterone in HC-treated rats. NanoString nCounter analysis indicated that adolescent HC administration impacted expression of genes related to synapses, white matter, neuroimmune, monoamine, and hormone signaling in the hypothalamus and medial prefrontal cortex. While no effects of HCs were seen on sociability in the social preference test or stress coping behavior in the forced swim test, adolescent HC administration diminished risk-assessment behaviors in the novelty-induced hypophagia paradigm and altered anxiety-like behavior in the open field test and elevated plus maze. Overall, these data suggest that exposure to contraceptive hormones during the critical developmental period of adolescence may shape the brain and behavior.

The effect of ovariectomy, 17β-estradiol treatment, and progesterone treatment on dopaminergic regulation of prepulse inhibition in adult and adolescent female mice

The aim of the present study was to investigate the role of ovarian hormones on dopaminergic regulation of prepulse inhibition (PPI), a measure of sensorimotor gating deficient in schizophrenia and other psychiatric illnesses. Either in adulthood (11 weeks of age) or adolescence (5 weeks of age), female mice underwent ovariectomy (OVX) and were implanted with 17β-estradiol, progesterone, or a combination of these hormones. All mice were tested in adulthood for the acute effect of the dopamine receptor agonist, apomorphine, on PPI. Apomorphine treatment reduced PPI in intact mice and this effect was blocked after OVX in adulthood. A low dose implant of 17β-estradiol prevented this OVX effect and reinstated apomorphine-induced PPI disruption. Following adolescent OVX, the effect of apomorphine was not altered and it significantly reduced PPI in adulthood. A low dose implant of 17β-estradiol following adolescent OVX effect blocked apomorphine-induced PPI disruption in adulthood. Apomorphine had no effect on PPI in any of the mice treated with the high dose of 17β-estradiol or a combination of low-dose 17β-estradiol and progesterone, irrespective of treatment age, suggesting an antipsychotic action. Apomorphine tended to disrupt PPI in mice treated with progesterone only, irrespective of age of OVX. These results suggest that in adult mice, circulating 17β-estradiol and progesterone play an important role in dopaminergic regulation of PPI. This role may develop during adolescence as similar effects of OVX and ovarian hormones were not observed following interventions in 5-week old mice. Our results also confirm and extend previous evidence that 17β-estradiol may have antipsychotic properties.

Early life adversity accelerates hypothalamic drive of pubertal timing in female rats with associated enhanced acoustic startle

Early life adversity in the form of childhood maltreatment in humans or as modeled by maternal separation (MS) in rodents is often associated with an earlier emergence of puberty in females. Earlier pubertal initiation is an example of accelerated biological aging and predicts later risk for anxiety in women, especially in populations exposed to early life trauma. Here we investigated external pubertal markers as well as hypothalamic gene expression of pubertal regulators kisspeptin and gonadotropin-releasing hormone, to determine a biological substrate for MS-induced accelerated puberty. We further investigated a mechanism by which developmental stress might regulate pubertal timing. As kisspeptin and gonadotropin-releasing hormone secretion are typically inhibited by corticotropin releasing hormone at its receptor CRH-R1, we hypothesized that MS induces a downregulation of Crhr1 gene transcription in a cell-specific manner. Finally, we explored the association between pubertal timing and anxiety-like behavior in an acoustic startle paradigm, to drive future preclinical research linking accelerated puberty and anxiety. We replicated previous findings that MS leads to earlier puberty in females but not males, and found expression of kisspeptin and gonadotropin-releasing hormone mRNA to be prematurely increased in MS females. RNAscope confirmed increased expression of these genes, and further revealed that kisspeptin-expressing neurons in females were less likely to express Crhr1 after MS. Early puberty was associated with higher acoustic startle magnitude in females. Taken together, these findings indicate precocial maturation of central pubertal timing mechanisms after MS, as well as a potential role of CRH-R1 in these effects and an association with a translational measure of anxiety.