Sex‐specific impact of brain estrogen deficiency on astrocyte reactivity, neurodegeneration, and memory loss in aromatase knockout mouse models

Abstract Background Nearly two‐thirds of Americans with Alzheimer’s disease (AD) are women, however, the molecular mechanisms underlying this sex difference in AD vulnerability remain unclear. Prior research has reported that women with AD have lower brain estrogen. Yet, how estrogen deficiency modulates this sex difference in AD is not well understood. Aromatase, the key enzyme for estrogen biosynthesis, is expressed in both neurons and astrocytes of the brain, with high levels in the hippocampus. To explore the underlying mechanism of estrogen deficiency in sex‐specific AD vulnerability, we generated mouse models with brain‐specific aromatase knockout (bArKO) and whole‐body total aromatase knockout (tArKO). Method We performed a series of memory and behavior tests including spontaneous alternation, social interaction, and tail suspension tests on 6‐ and 19‐month‐old bArKO and tArKO mice with both sexes (n = 10/group). Hippocampus tissues from these mice (n = 3∼4) were collected for bulk RNA‐seq and qPCR. Brain tissues (n = 5) were fixed and stained for astrocytes and neurons by immunofluorescence. Serum and tissue estrogen were measured using liquid chromatography‐mass spectrometry. Result Aromatase deletion decreased brain estrogen levels in bArKO mice and circulating and brain estrogen levels in tArKO mice. Impairments of spatial working memory and social interaction behavior were found in 19‐month‐old female bArKO and tArKO mice. Female tArKO mice also displayed depression‐like behavior at 6‐ and 19‐month‐old. The number of neurons in the CA1 region was significantly decreased in 19‐month‐old female (but not male) tArKO mice. Bulk RNA‐seq showed abnormal expression of genes associated with astrocyte reactivity (e.g., Gfap, Ctgf, Apoe, Lcn2, Sparc, Bdnf, Col1a1, Col1a2) only in aged female bArKO mice. Given growing evidence indicating a causal relationship between neurotoxic reactive astrocytes and neurodegeneration, this finding indicates brain estrogen deficiency triggering neurotoxic astrocyte reactivity in the hippocampus of aged female bArKO mice. Conclusion Our findings provide novel mechanisms that link estrogen deficiency to sex‐specific astrocyte reactivity in the hippocampus, and neurodegeneration and memory loss in aged female mice. Future studies will focus on defining impact of estrogen signaling deficiency on AD mouse models and identifying druggable targets to inform the development of new therapeutic strategies for the prevention and treatment of AD.