Abstract
Estradiol provision via neural aromatization decreases neuro-inflammation and –degeneration, but almost nothing is known about the interactions between the peripheral immune system and brain aromatase. Given the vulnerability of the CNS we reasoned that brain aromatization may protect circuits from the threats of peripheral infection; perhaps shielding cells that are less resilient from the degeneration associated with peripheral infection or trauma. Lipopolysaccharide (LPS) or vehicle was administered peripherally to adult zebra finches and sickness behavior was recorded 2 or 24 hours later. The central transcription of cytokines and aromatase was measured, as were telencephalic aromatase activity and immunoreactive aromatase (24 hour time point only). Two hours post LPS, sickness-like behaviors increased, the transcription of IL-1β was higher in both sexes, and TNFα was elevated in females. 24 hours post-LPS, the behavior of LPS birds was similar to controls, and cytokines had returned to baseline, but aromatase mRNA and activity were elevated in both sexes. Immunocytochemistry revealed greater numbers of aromatase-expressing neurons in LPS birds. These data suggest that the activation of the immune system via peripheral endotoxin increases neuronal aromatase; a mechanism that may rapidly generate a potent anti-neuroinflammatory steroid in response to peripheral activation of the immune system.
Highlights
Estrogens are established modulators of vertebrate anatomy and physiology throughout the lifespan
In adult zebra finches of both sexes, we found that a peripheral injection of LPS: increased; [1] sickness-related behavior transiently, [2] cytokine expression rapidly and transiently and, [3] aromatase mRNA, activity and expression
Increases in aromatase were observed at a time when cytokine-expression had resolved to baseline levels. These data suggest that a peripheral inflammatory response is sufficient to induce neuronal aromatase in the brain
Summary
Estrogens are established modulators of vertebrate anatomy and physiology throughout the lifespan. The range of physiological processes affected by E2 has broadened considerably and includes learning, memory, pain, balance, and mood, among others7–14 Part of this expansion includes a link between E2 and inflammatory signaling. Post-menopausal women who are not on hormone replacement therapy have higher indices of inflammation compared to premenopausal women11 This is likely due to a loss of circulating E2 since the administration of this estrogen decreases circulating cytokine levels in mice, and microglial activation following lipopolysaccharide (LPS) in vitro. Circulating E2 appears to be a potent neuroprotective signal involving (anti-) inflammatory pathways in multiple vertebrate tissues in the periphery. Zebra finches do not show the wave of secondary degeneration following brain injury that is prominent in mammalian models26 This wave of secondary degeneration is only evident following aromatase inhibition. Finches appear to possess a powerful mechanism that allows the brain to be protected following damage, and E2 may play a large role in regulating cell turnover and inflammatory signaling following insult
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