madman
Super Moderator
Abstract
The aromatase cytochrome P450 (P450arom) enzyme, or estrogen synthase, which is coded by the CYP19A1 gene, is widely expressed in a subpopulation of excitatory and inhibitory neurons, astrocytes, and other cell types in the human brain. Experimental studies in laboratory animals indicate a prominent role of brain aromatization of androgens to estrogens in regulating different brain functions. However, the consequences of aromatase expression in the human brain remain poorly understood. Here, we summarize the current knowledge about aromatase expression in the human brain, abundant in the thalamus, amygdala, hypothalamus, cortex, and hippocampus, and discuss its role in the regulation of sensory integration, body homeostasis, social behavior, cognition, language, and integrative functions. Since brain aromatase is affected by neurodegenerative conditions and may participate in sex-specific manifestations of autism spectrum disorders, major depressive disorder, multiple sclerosis, stroke, and Alzheimer’s disease, we discuss future avenues for research and potential clinical and therapeutic implications of the expression of aromatase in the human brain.
Introduction
Part of the actions of androgens in the body is exerted after their conversion to estrogens by the enzyme aromatase cytochrome P450 (P450arom) or estrogen synthase. The enzyme converts androst-4-ene-3,17-dione (androstenedione) and testosterone into estrone and estradiol, respectively (Fig. 1). Half a century ago, Naftolin and collaborators reported the existence of aromatase activity in samples of human brain tissue isolated from male fetuses.1,2 The implication of this finding was that aromatizable androgens can regulate human brain function not only through the androgen receptors (AR) but also by the activation of estrogen receptors (ERs) after their conversion to estrogenic metabolites. In addition, although aromatase activity in the brain probably does not affect the overall concentration of androgens, it is plausible that by decreasing the levels of androgens at very specific intracellular domains, aromatase activity may also contribute toward modulating AR signaling in the human brain.
Studies in different vertebrate species, from fish to mammals, have shown that aromatase is expressed in the developing and adult brain and the spinal cord of both males and females. Central aromatase activity participates in a variety of functions that are not restricted to the control of the neuroendocrine axis and the regulation of reproduction or sex differences, but this includes the processing of sensory information, the coordination of sensory inputs with motor outputs, the expression of affective behavior, and the modulation of learning and memory.3–10 To exert these actions, estradiol generated by brain aromatase regulates cellular signaling, gene expression, synaptic transmission, and synaptic plasticity,11–14 and it is part of the endogenous neuroprotective and anti-inflammatory response activated in neural tissue after injury.15,16
Not all of these roles of the enzyme described in animal studies have been ascertained in humans. However, human studies have significantly advanced in recent years and we have considerable new information on the anatomical and cellular distribution of the enzyme in the human central nervous system (CNS), together with new hints on its physiological implication in the neural processing of sensory integration, the modulation of social behavior and cognition, and the central control of body homeostasis. Available data also indicate that brain aromatase expression is altered with aging and under neurodegenerative conditions. Further, genetic and neuropathological findings suggest that the enzyme may participate in the manifestation of brain diseases, including major depressive disorder, autism spectrum disorders (ASDs), and neurodegenerative diseases. Here, we review the available information on the distribution and function of aromatase in the human brain, discussing future avenues for research and potential clinical and therapeutic implications.
*Aromatase Expression and Distribution in the Human Brain
*Cellular Localization
*Physiological and Pathophysiological Function of Brain Aromatase
-Thalamus: sensory integration
-Amygdala and hypothalamus: body homeostasis, social behavior, and major -depressive disorder
-Cerebral neocortex and hippocampus: cognition, language, and integrative functions
*Alterations of Brain Aromatase with Aging
*Brain Aromatase Under Pathological Conditions
-Aromatase in ASDs
-Aromatase and epilepsy
-Aromatase and stroke
-Aromatase and chronic neurodegenerative diseases
-Aromatase and sex differences in neurodegenerative diseases
*Conclusions and Perspectives
In conclusion, there are many unsolved questions and gaps in our knowledge on human brain aromatase that remain to be explored by future research. However, the limited available information that has been reviewed here suggests that the aromatization of androgens to estrogens by the human nervous tissue is involved in many more physiological and pathological processes than previously believed.
The aromatase cytochrome P450 (P450arom) enzyme, or estrogen synthase, which is coded by the CYP19A1 gene, is widely expressed in a subpopulation of excitatory and inhibitory neurons, astrocytes, and other cell types in the human brain. Experimental studies in laboratory animals indicate a prominent role of brain aromatization of androgens to estrogens in regulating different brain functions. However, the consequences of aromatase expression in the human brain remain poorly understood. Here, we summarize the current knowledge about aromatase expression in the human brain, abundant in the thalamus, amygdala, hypothalamus, cortex, and hippocampus, and discuss its role in the regulation of sensory integration, body homeostasis, social behavior, cognition, language, and integrative functions. Since brain aromatase is affected by neurodegenerative conditions and may participate in sex-specific manifestations of autism spectrum disorders, major depressive disorder, multiple sclerosis, stroke, and Alzheimer’s disease, we discuss future avenues for research and potential clinical and therapeutic implications of the expression of aromatase in the human brain.
Introduction
Part of the actions of androgens in the body is exerted after their conversion to estrogens by the enzyme aromatase cytochrome P450 (P450arom) or estrogen synthase. The enzyme converts androst-4-ene-3,17-dione (androstenedione) and testosterone into estrone and estradiol, respectively (Fig. 1). Half a century ago, Naftolin and collaborators reported the existence of aromatase activity in samples of human brain tissue isolated from male fetuses.1,2 The implication of this finding was that aromatizable androgens can regulate human brain function not only through the androgen receptors (AR) but also by the activation of estrogen receptors (ERs) after their conversion to estrogenic metabolites. In addition, although aromatase activity in the brain probably does not affect the overall concentration of androgens, it is plausible that by decreasing the levels of androgens at very specific intracellular domains, aromatase activity may also contribute toward modulating AR signaling in the human brain.
Studies in different vertebrate species, from fish to mammals, have shown that aromatase is expressed in the developing and adult brain and the spinal cord of both males and females. Central aromatase activity participates in a variety of functions that are not restricted to the control of the neuroendocrine axis and the regulation of reproduction or sex differences, but this includes the processing of sensory information, the coordination of sensory inputs with motor outputs, the expression of affective behavior, and the modulation of learning and memory.3–10 To exert these actions, estradiol generated by brain aromatase regulates cellular signaling, gene expression, synaptic transmission, and synaptic plasticity,11–14 and it is part of the endogenous neuroprotective and anti-inflammatory response activated in neural tissue after injury.15,16
Not all of these roles of the enzyme described in animal studies have been ascertained in humans. However, human studies have significantly advanced in recent years and we have considerable new information on the anatomical and cellular distribution of the enzyme in the human central nervous system (CNS), together with new hints on its physiological implication in the neural processing of sensory integration, the modulation of social behavior and cognition, and the central control of body homeostasis. Available data also indicate that brain aromatase expression is altered with aging and under neurodegenerative conditions. Further, genetic and neuropathological findings suggest that the enzyme may participate in the manifestation of brain diseases, including major depressive disorder, autism spectrum disorders (ASDs), and neurodegenerative diseases. Here, we review the available information on the distribution and function of aromatase in the human brain, discussing future avenues for research and potential clinical and therapeutic implications.
*Aromatase Expression and Distribution in the Human Brain
*Cellular Localization
*Physiological and Pathophysiological Function of Brain Aromatase
-Thalamus: sensory integration
-Amygdala and hypothalamus: body homeostasis, social behavior, and major -depressive disorder
-Cerebral neocortex and hippocampus: cognition, language, and integrative functions
*Alterations of Brain Aromatase with Aging
*Brain Aromatase Under Pathological Conditions
-Aromatase in ASDs
-Aromatase and epilepsy
-Aromatase and stroke
-Aromatase and chronic neurodegenerative diseases
-Aromatase and sex differences in neurodegenerative diseases
*Conclusions and Perspectives
In conclusion, there are many unsolved questions and gaps in our knowledge on human brain aromatase that remain to be explored by future research. However, the limited available information that has been reviewed here suggests that the aromatization of androgens to estrogens by the human nervous tissue is involved in many more physiological and pathological processes than previously believed.
