Single cell resolution of neurosteroidogenesis in the murine brain: de novo biosynthesis

in Journal of Endocrinology
Authors:
Prasanthi P Koganti Department of Animal Science, College of Agriculture and Life Sciences, Cornell University, Ithaca, New York, USA

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Vimal Selvaraj Department of Animal Science, College of Agriculture and Life Sciences, Cornell University, Ithaca, New York, USA

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https://orcid.org/0000-0002-8728-3765

Correspondence should be addressed to V Selvaraj: vs88@cornell.edu

This paper forms part of a special collection marking 30 Years Since the Identification and Characterization of the StAR Protein. The Guest Editors for this collection were Doug Stocco, Barbara Clark and Ernesto Podesta.

DOI:
https://doi.org/10.1530/JOE-24-0318
Volume/Issue:
Volume 265: Issue 3
Article Type:
Research Article
Article ID:
e240318
Online Publication Date:
07 May 2025
Copyright:
© the author(s) 2025
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Neurosteroids synthesized within the central nervous system play essential roles in modulating neurotransmission, providing neuroprotection, regulating immune responses, influencing behavior and cognition and mediating stress physiology. Despite their broad significance, the specific brain cell types capable of de novo steroid synthesis from cholesterol remain poorly defined. In this study, we analyzed single-cell transcriptomic data to map steroidogenic gene expression across cell populations in the murine brain, focusing on the de novo production of the neurosteroid pregnenolone. Our findings reveal that de novo steroidogenesis, as marked by Cyp11a1 expression, is predominantly confined to specific neuronal subtypes, particularly glutamatergic neurons of the intra- and extra-telencephalic regions and the corticothalamic layer. In contrast, Star expression, which is essential for mitochondrial cholesterol import, was more broadly distributed, occurring in both neuronal and non-neuronal cells (including oligodendrocytes, astrocytes, immune cells and vascular cells). In these non-neuronal populations, Star was notably co-expressed with mitochondrial Cyp27a1, indicative of bile acid synthesis rather than neurosteroidogenesis. This distinction highlights that Star expression alone is not a reliable marker of de novo neurosteroidogenic capacity in the brain, as its functional significance depends on the broader enzymatic context in which it occurs. The resulting single-cell map of de novo neurosteroid biosynthetic capacity across brain regions, including modest sex-associated differences, provides a foundational framework for understanding neurosteroid signaling in distinct cell types and its relevance to brain physiology and pathophysiology.

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Print ISSN:
0022-0795
Online ISSN:
1479-6805
Copyright:
© the author(s) 2025
Article ID:
e240318
Article Type:
Research Article
Received Date:
10 Nov 2024
Rev-recd:
08 Apr 2025
Accepted Date:
22 Apr 2025
Print Publication Date:
01 Jun 2025
Online Publication Date:
07 May 2025
Keywords:
neuron; astrocyte; oligodendrocyte; microglia; pregnenolone; bile

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