SummaryFeeding requires the integration of homeostatic drives with emotional states relevant to food procurement in potentially hostile environments. The ventromedial hypothalamus (VMH) regulates feeding and anxiety, but how these are controlled in a concerted manner remains unclear. Using pharmacogenetic, optogenetic, and calcium imaging approaches with a battery of behavioral assays, we demonstrate that VMH steroidogenic factor 1 (SF1) neurons constitute a nutritionally sensitive switch, modulating the competing motivations of feeding and avoidance of potentially dangerous environments. Acute alteration of SF1 neuronal activity alters food intake via changes in appetite and feeding-related behaviors, including locomotion, exploration, anxiety, and valence. In turn, intrinsic SF1 neuron activity is low during feeding and increases with both feeding termination and stress. Our findings identify SF1 neurons as a key part of the neurocircuitry that controls both feeding and related affective states, giving potential insights into the relationship between disordered eating and stress-associated psychological disorders in humans.
Astrocytes are key players in the progression of amyotrophic lateral sclerosis (ALS). Previously, gene expression profiling of astrocytes from the pre-symptomatic stage of the SOD1G93A model of ALS has revealed reduced lactate metabolism and altered trophic support. Here, we have performed microarray analysis of symptomatic and late-stage disease astrocytes isolated by laser capture microdissection (LCM) from the lumbar spinal cord of the SOD1G93A mouse to complete the picture of astrocyte behavior throughout the disease course. Astrocytes at symptomatic and late-stage disease show a distinct up-regulation of transcripts defining a reactive phenotype, such as those involved in the lysosome and phagocytic pathways. Functional analysis of hexosaminidase B enzyme activity in the spinal cord and of astrocyte phagocytic ability has demonstrated a significant increase in lysosomal enzyme activity and phagocytic activity in SOD1G93A vs. littermate controls, validating the findings of the microarray study. In addition to the increased reactivity seen at both stages, astrocytes from late-stage disease showed decreased expression of many transcripts involved in cholesterol homeostasis. Staining for the master regulator of cholesterol synthesis, SREBP2, has revealed an increased localization to the cytoplasm of astrocytes and motor neurons in late-stage SOD1G93A spinal cord, indicating that down-regulation of transcripts may be due to an excess of cholesterol in the CNS during late-stage disease possibly due to phagocytosis of neuronal debris. Our data reveal that SOD1G93A astrocytes are characterized more by a loss of supportive function than a toxic phenotype during ALS disease progression and future studies should focus upon restorative therapies.
Arcuate nucleus agouti–related peptide (AgRP) neurons play a central role in feeding and are under complex regulation by both homeostatic hormonal and nutrient signals and hypothalamic neuronal pathways. Feeding may also be influenced by environmental cues, sensory inputs, and other behaviors, implying the involvement of higher brain regions. However, whether such pathways modulate feeding through direct synaptic control of AgRP neuron activity is unknown. Here, we show that nociceptin-expressing neurons in the anterior bed nuclei of the stria terminalis (aBNST) make direct GABAergic inputs onto AgRP neurons. We found that activation of these neurons inhibited AgRP neurons and feeding. The activity of these neurons increased upon food availability, and their ablation resulted in obesity. Furthermore, these neurons received afferent inputs from a range of upstream brain regions as well as hypothalamic nuclei. Therefore, aBNST GABAergic nociceptin neurons may act as a gateway to feeding behavior by connecting AgRP neurons to both homeostatic and nonhomeostatic neuronal inputs.
The brain needs to track body energy state to optimize physiology and behavior. Important information about current and future energy states is contained in minute-to-minute fluctuations in blood glucose. However, it is unclear whether brain glucose sensors are capable of responding to this temporal structure to extract such information. In behaving mammals, hypothalamic hypocretin/orexin neurons (HONs) control arousal and are proposed to sense energy balance, yet recent studies show that HON activity varies rapidly (over seconds) with locomotion. It remains unknown if and how HONs reflect blood glucose fluctuations. Here, for the first time, we co-monitored HON activity and blood glucose in behaving mice, uncovering inhibition of HONs by rising blood glucose. Surprisingly, peak HON signals (population waves) anticipated peak glucose deviations by several minutes. In multivariate analysis of diverse HON activity correlates (locomotion, metabolic variables), the glucose temporal gradient (negative first derivative) emerged as prime predictor of HON population activity on the minute timescales, thereby explaining this anticipatory response. Furthermore, 2-photon imaging of >900 individual HONs revealed parallel communication of absolute blood glucose values and their derivatives in distinct HON subsets. Thus, HONs transmit multiplexed slowly and rapidly changing information, and, in the slow bandwidth, extract temporal features from blood glucose dynamics that suggest a hybrid of anticipatory and proportional logic in brain responses to blood glucose.
The ability to perform skilled arm movements is central to everyday life, as limb impairments in common neurologic disorders such as stroke demonstrate. Skilled arm movements require adaptation of motor commands based on discrepancies between desired and actual movements, called sensory errors. Studies in humans show that this involves predictive and reactive movement adaptations to the errors, and also requires a general motivation to move. How these distinct aspects map onto defined neural signals remains unclear, because of a shortage of equivalent studies in experimental animal models that permit neural-level insights. Therefore, we adapted robotic technology used in human studies to mice, enabling insights into the neural underpinnings of motivational, reactive, and predictive aspects of motor adaptation. Here, we show that forelimb motor adaptation is regulated by neurons previously implicated in motivation and arousal, but not in forelimb motor control: the hypothalamic orexin/hypocretin neurons (HONs). By studying goal-oriented mouse-robot interactions in male mice, we found distinct HON signals occur during forelimb movements and motor adaptation. Temporally-delimited optosilencing of these movement-associated HON signals impaired sensory error-based motor adaptation. Unexpectedly, optosilencing affected neither task reward or execution rates, nor motor performance in tasks that did not require adaptation, indicating that the temporally-defined HON signals studied here were distinct from signals governing general task engagement or sensorimotor control. Collectively, these results reveal a hypothalamic neural substrate regulating forelimb motor adaptation.
Internally and externally triggered movement is crucial for survival and is controlled by multiple interconnected neuronal populations spanning many brain areas. Lateral hypothalamic orexin/hypocretin neurons are thought to play a slow, modulatory part in this scheme through their key role in promoting metabolism and wakefulness. However, it is unknown whether orexin/hypocretin neurons participate in rapid neural processing, leading to immediate movement. Furthermore, their role in sensorimotor transformations remains unknown. Here we use cellular-resolution Ca 2+ imaging and optogenetics to show that orexin/hypocretin cells are instantaneous regulators of self-generated and sensory-evoked movement. They are activated before and during movement, preventing this activation reduces self-generated locomotion, and optogenetic mimicry of this transient activation rapidly initiates locomotion. We find that the same orexin neurons whose activity predicts movement initiation are rapidly controllable by external sensory stimuli, and silencing orexin cells during sensation prevents normal motor performance. These findings place orexin neurons in a physiological position of unexpectedly rapid and strong sensorimotor control. * -( Figure 3E), where S is spike output, F is light pulse frequency, P is movement probability, EC50 is half-maximal response and IC50 half-maximal decrease. Fitting was done using custom routines in Matlab.
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