Steroid hormones can modulate motivated behaviors through the mesocorticolimbic system. Gonadectomy (GDX) is a common method to determine how steroids influence the mesocorticolimbic system, and caloric restriction (CR) is often used to invigorate motivated behaviors. A common assumption is that the effects of these manipulations on brain steroid levels reflects circulating steroid levels. We now know that the brain regulates local steroid levels in a region-specific manner; however, previous studies have low spatial resolution. Using ultrasensitive liquid chromatography tandem mass spectrometry, we examined steroids in microdissected regions of the mesocorticolimbic system (ventral tegmental area, nucleus accumbens, medial prefrontal cortex). We examined whether GDX or CR influences systemic and local steroids, particularly testosterone (T) and steroidogenic enzyme transcripts. Adult male rats underwent a GDX surgery and/or CR for either 2 or 6 weeks. Levels of T, the primary steroid of interest, were higher in all brain regions than in the blood, whereas corticosterone (CORT) was lower in the brain than in the blood. Importantly, GDX completely eliminated T in the blood and lowered T in the brain. Yet, T remained present in the brain, even 6 weeks after GDX. CR decreased both T and CORT in the blood and brain. Steroidogenic enzyme (Cyp17a1, 3β-hydroxysteroid dehydrogenase, aromatase) transcripts and androgen receptor transcripts were expressed in the mesocorticolimbic system and differentially affected by GDX and CR. Together, these results suggest that T is synthesized within the mesocorticolimbic system. These results provide a foundation for future studies examining how neurosteroids influence behaviors mediated by the mesocorticolimbic system.
Thymocyte positive and negative selection are critical for generation of a competent and self-tolerant T cell repertoire. Glucocorticoids (GCs) protect thymocytes from T cell receptor (TCR)-induced death, and thymocyte-specific GC receptor (GR) deletion amplifies negative selection, weakening the TCR repertoire. Circulating GCs are secreted by the adrenals, but levels fluctuate widely with time of day and in response to stressors. To avoid such variation, thymus GCs might be regulated independently of the adrenals, as thymic epithelial cells (TECs) and possibly thymocytes express GC-synthetic enzymes. Whether local GC production is sufficient to affect thymocyte development in the presence of adrenal GCs, however, is unknown. Here, we have found that corticosterone, the major mouse GC, was locally elevated in the thymus compared to the blood, and that cultured thymus produced corticosterone from endogenous substrates via GC-synthetic enzyme activity. To test the source and importance of local GC synthesis in vivo, we generated mice with targeted deletion of the GC-synthetic enzyme Cyp11b1 in TECs (Cyp11b1foxn1-Cre) or thymocytes (Cyp11b1lck-Cre). As a measure of GC signaling we quantified thymocyte expression of the GC-responsive gene Gilz. Gilz mRNA was normal in Cyp11b1lck-Cre but reduced in Cyp11b1foxn1-Cre thymocytes, with a reduction equivalent to that in GR-deficient thymocytes. Basal GR signaling is thus driven overwhelmingly by TEC-rather than adrenal-derived corticosterone. These findings demonstrate the importance of paracrine GC function in vivo, and are consistent with a role for paracrine GCs in thymocyte selection.
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