Hypothalamic Neurons Research Articles

Neuronal HIF-1α expression in mediobasal hypothalamus affects glycolipid metabolism and body weight in mice fed with high-fat diet.

This study aimed to explore the interaction between the expression of neuronal HIF-1α in the mediobasal hypothalamus and food intake, glycolipid metabolism and body weight (BW) in mice consuming high-fat diet (HFD). In HIF-1αflox/flox mice, AAV-hSyn-GFP (NC group) or AAV-hSyn-cre-GFP (KD group) virus was injected into medial base of the hypothalamus. Frozen brain tissue sections confirmed the presence of the virus within the hypothalamus of mice after 28 days of AAV injection, including reporter signals within the arcuate nucleus, DMH and VMH. Consistently, the levels of HIF-1α mRNA in the ventral hypothalamus were significantly lower in the KD group compared to the NC group. These KD mice also demonstrated significantly increased food intake, body weight (BW), total cholesterol (TC), high-density lipoprotein (HDL), low-density lipoprotein (LDL) and serum insulin, combined with higher blood glucose, compared to NC animals. However, the levels of triglycerides and FFA were similar in both groups. Significant differences in p-Akt levels were not observed in the skeletal muscle, liver or epididymal fat in KD mice after insulin injection. In conclusion, the knockdown of HIF-1α within the neurons of mediobasal hypothalamus results in an increase in the appetite of mice fed with HFD, which in turn leads to a significant dysregulation of lipid and glucose metabolism and a corresponding increase in weight. Therefore, the neuronal HIF-1α expression in the mediobasal hypothalamus may be a critical regulator of glycolipid metabolism and body weight control when a high-fat diet is consumed.

Glp1r-Lepr coexpressing neurons modulate the suppression of food intake and body weight by a GLP-1/leptin dual agonist.

Glucagon-like peptide-1 (GLP-1) and leptin signal recent feeding and long-term energy stores, respectively, and play complementary roles in the modulation of energy balance. Previous work using single-cell techniques in mice revealed the existence of a population of leptin receptor (Lepr)-containing dorsomedial hypothalamus (DMH) neurons marked by the expression of GLP-1 receptor (Glp1r; LepRGlp1r neurons) that play important roles in the control of feeding and body weight by leptin. Here, we demonstrate the existence of a population of LepRGlp1r neurons in the DMHs of nonhuman primates (NHPs), suggesting the potential translational relevance of these neurons. Consequently, we developed a GLP-1R/LepR dual agonist and demonstrated the physiological activity of both components in vivo using leptin-deficient and Lepr-deficient murine models. We further found roles for LepRGlp1r neurons in mediating the dual agonist's efficacy on food intake and body weight loss. Ablating Lepr in Glp1r-expressing neurons (LeprGlp1rKO mice) abrogated the suppression of food intake by the dual agonist. Furthermore, reactivation of Glp1r expression in Lepr neurons on an otherwise Glp1r-null background (Glp1rLeprRe mice) was sufficient to permit the suppression of food intake and body weight by the dual agonist. Hence, LepRGlp1r neurons represent targets for a GLP-1R/LepR dual agonist that potently reduces food intake and body weight.

Molecular connectomics reveals a glucagon-like peptide 1-sensitive neural circuit for satiety.

Liraglutide and other glucagon-like peptide 1 receptor agonists (GLP-1RAs) are effective weight loss drugs, but how they suppress appetite remains unclear. One potential mechanism is by activating neurons that inhibit the hunger-promoting Agouti-related peptide (AgRP) neurons of the arcuate hypothalamus (Arc). To identify these afferents, we developed a method combining rabies-based connectomics with single-nucleus transcriptomics. Here, we identify at least 21 afferent subtypes of AgRP neurons in the mouse mediobasal and paraventricular hypothalamus, which are predicted by our method. Among these are thyrotropin-releasing hormone (TRH)+ Arc (TRHArc) neurons, inhibitory neurons that express the Glp1r gene and are activated by the GLP-1RA liraglutide. Activating TRHArc neurons inhibits AgRP neurons and feeding, probably in an AgRP neuron-dependent manner. Silencing TRHArc neurons causes overeating and weight gain and attenuates liraglutide's effect on body weight. Our results demonstrate a widely applicable method for molecular connectomics, comprehensively identify local inputs to AgRP neurons and reveal a circuit through which GLP-1RAs suppress appetite.

Neuropeptidergic input from the lateral hypothalamus to the suprachiasmatic nucleus alters the circadian period in mice.

In mammals, the central circadian clock is located in the suprachiasmatic nucleus (SCN) of the hypothalamus, which transmits circadian information to other brain regions and regulates the timing of sleep and wakefulness. Neurons in the lateral hypothalamus (LH), particularly those producing melanin-concentrating hormone (MCH)- and orexin are key regulators of sleep and wakefulness. Although the SCN receives non-photic input from other brain regions, the mechanisms of functional input from the LH to the SCN remain poorly understood. Here, we show that orexin and MCH peptides influence the circadian period within the SCN of both sexes. When these neurons are ablated, the circadian behavioral rhythms are lengthened under constant darkness. Using anterograde and retrograde tracing, we found that orexin and MCH neurons project to the SCN. Furthermore, the application of these peptides to cultured SCN slices shortened circadian rhythms and reduced intracellular cAMP levels. Additionally, pharmacological reduction of intracellular cAMP levels similarly shortened the circadian period in SCN slices. These findings suggest that orexin and MCH peptides from the LH contribute to the modulation of the circadian period in the SCN.Significance statement In mammals, the central circadian clock is located in the suprachiasmatic nucleus (SCN) of the hypothalamus, where it regulates circadian rhythms, including sleep and wakefulness. The SCN receives both neuronal and humoral input signals from external brain regions, which can modify circadian rhythms within the SCN. While several brain regions that project to the SCN have been anatomically identified, the specific regions, neuronal cell types, and neurotransmitters that influence SCN circadian rhythms remain largely uncharacterized. This study identifies two neuronal populations within the lateral hypothalamus that project to the SCN and modulate the circadian period.

MicroRNA-34a-5p regulates agouti-related peptide via krüppel-like factor 4 and is disrupted by bisphenol A in hypothalamic neurons

Obesity is a complex disease marked by increased adiposity and impaired metabolic function. While diet and lifestyle are primary causes, endocrine-disrupting chemicals (EDCs), such as bisphenol A (BPA), significantly contribute to obesity. BPA, found in plastic consumer products, accumulates in the hypothalamus and dysregulates energy homeostasis by disrupting the neuropeptide Y (NPY)/agouti-related peptide (AgRP) and pro-opiomelanocortin (POMC) neurons.However, the precise molecular mechanisms of how BPA disrupts neuropeptide expression remains unclear. We hypothesized that microRNAs (miRNAs), which regulate approximately 60% of the human protein-coding genome and are crucial for hypothalamic energy regulation, may mediate the effects of BPA on Agrp. Using the TargetScanMouse 8.0 and DIANA microT bioinformatics tools, we identified miR-501-5p as a potential miRNA that directly regulates Agrp and the miR-34 family as miRNAs that indirectly regulate Agrp through its transcription factor krüppel-like factor 4 (KLF4). We found that in an immortalized NPY/AgRP-expressing cell line, mHypoE-41, miR-501-5p unexpectedly upregulated Agrp, while miR-34a-5p reduced Klf4 and Agrp mRNA levels. Serum starvation reduced miR-34a-5p levels and elevated Agrp mRNA levels, suggesting a potential role in AgRP regulation. Inhibiting the miR-34a-5p interaction with the Klf4 3′UTR using a specific target site blocker prevented the downregulation of both Klf4 and Agrp, suggesting miR-34a-5p alters Agrp mRNA levels via regulation of KLF4. BPA treatment increased Agrp and Klf4 expression while simultaneously decreasing miR-34a-5p levels, indicating miR-34a-5p may play a role in BPA-mediated dysregulation of Agrp. Overall, this study highlights indirect miRNA-based regulation of Agrp, which can also be dysregulated by obesogens, such as BPA.

Kisspeptin fiber and receptor distribution analysis suggests its potential role in central sensorial processing and behavioral state control.

Kisspeptin (KP) signaling in the brain is defined by the anatomical distribution of KP-producing neurons, their fibers, receptors, and connectivity. Technological advances have prompted a re-evaluation of these chemoanatomical aspects, originally studied in the early years after the discovery of KP and its receptor Kiss1r. We have previously characterized(1) seven KP neuronal populations in the mouse brain at the mRNA level, including two novel populations, and examined their short-term response to gonadectomy. In this study, we mapped KP fiber distribution in rats and mice using immunohistochemistry under intact and short- and long-term post-gonadectomy conditions. Kiss1r mRNA expression was examined via RNAscope, in relation to vesicular GABA transporter ( Slc32a1 ) in whole mouse brain and to KP and vesicular glutamate transporter 2 ( Kiss1 and Slc17a6 ) in hypothalamic RP3V and arcuate regions. We identified KP fibers in 118 brain regions, primarily in extra-hypothalamic areas associated with sensorial processing and behavioral state control. KP-immunoreactive fiber density and distribution were largely unchanged by gonadectomy. Kiss1r was expressed prominently in sensorial and state control regions such as septal nuclei, the suprachiasmatic nucleus, locus coeruleus, hippocampal layers, thalamic nuclei, and cerebellar structures. Co-expression of Kiss1r and Kiss1 was observed in hypothalamic neurons, suggesting both autocrine and paracrine KP signaling mechanisms. These findings enhance our understanding of KP signaling beyond reproductive functions, particularly in sensorial and behavioral state regulation. This study opens new avenues for investigating KP's role in controlling complex physiological processes, including those not related to reproduction.

A biological rhythm in the hypothalamic system links sleep-wake cycles with feeding-fasting cycles

The hypothalamus senses the appetite-regulating hormones and also coordinates the metabolic function in alignment with the circadian rhythm. This alignment is essential to maintain the physiological conditions that prevent clinically important comorbidities, such as obesity or type-2 diabetes. However, a complete model of the hypothalamus that relates food intake with circadian rhythms and appetite hormones has not yet been developed. In this work, we present a computational model that accurately allows interpreting neural activity in terms of hormone regulation and sleep-wake cycles. We used a conductance-based model, which consists of a system of four differential equations that considers the ionotropic and metabotropic receptors, and the input currents from homeostatic hormones. We proposed a logistic function that fits available experimental data of insulin hormone concentration and added it into a short-term ghrelin model that served as an input to our dynamical system. Our results show a double oscillatory system, one synchronized by light-regulated sleep-wake cycles and the other by food-regulated feeding-fasting cycles. We have also found that meal timing frequency is highly relevant for the regulation of the hypothalamus neurons. We therefore present a mathematical model to explore the plausible link between the circadian rhythm and the endogenous food clock.

Transforming growth factor β-2 is rhythmically expressed in both WT and BMAL1-deficient hypothalamic neurons and regulates neuropeptide Y: Disruption by palmitate

The hypothalamus contains neuropeptide Y (NPY)-expressing neurons that control food intake and regulate energy homeostasis. During the development of obesity, neuroinflammation occurs in the hypothalamus before peripheral tissues, but the cytokines involved have not been thoroughly studied. Among them is the transforming growth factor beta (TGF-β) family of cytokines. Herein, we demonstrate that Tgfb 1–3, as well as its receptors Tgfbr1 and Tgfbr2, exhibit high levels of expression in the whole hypothalamus, primary hypothalamic culture, and immortalized hypothalamic neurons. Of interest, only Tgfb2 mRNA displays circadian expression in the immortalized hypothalamic neurons and maintains this rhythmicity in BMAL1-KO-derived hypothalamic neurons that are deficient of inherent clock gene rhythmicity. Although BMAL2 may serve as an alternative rhythm generation mechanism in the absence of BMAL1, its knockdown did not affect Tgfb2 expression. Treatment of immortalized NPY-expressing neurons with TGF-β2 upregulates the core circadian oscillators Bmal1 and Nr1d1, and importantly, also Npy mRNA expression. With obesity, the hypothalamus is exposed to elevated levels of palmitate, a saturated fatty acid that promotes neuroinflammation by upregulating pro-inflammatory cytokines. Palmitate treatment disrupts the expression of TGF-β signaling components, increases BMAL1 binding to the Tgfb2 5’ regulatory region, and upregulates Npy mRNA, whereas antagonizing TGFBRI attenuates the upregulation of Npy. These results suggest that hypothalamic neuronal TGF-β2 lies at the intersection of circadian rhythms, feeding neuropeptide control, and neuroinflammation. A better understanding of the underlying mechanisms that link nutrient excess to hypothalamic dysfunction is critical for the development of effective prevention and treatment strategies.

A normative framework dissociates need and motivation in hypothalamic neurons.

Physiological needs evoke motivational drives that produce natural behaviors for survival. In previous studies, the temporally intertwined dynamics of need and motivation have made it challenging to differentiate these two components. On the basis of classic homeostatic theories, we established a normative framework to derive computational models for need-encoding and motivation-encoding neurons. By combining the model-based predictions and naturalistic experimental paradigms, we demonstrated that agouti-related peptide (AgRP) and lateral hypothalamic leptin receptor (LHLepR) neuronal activities encode need and motivation, respectively. Our model further explains the difference in the dynamics of appetitive behaviors induced by optogenetic stimulation of AgRP or LHLepR neurons. Our study provides a normative modeling framework that explains how hypothalamic neurons separately encode need and motivation in the mammalian brain.

Ginsenoside Rg1 promotes non-rapid eye movement sleep via inhibition of orexin neurons of the lateral hypothalamus and corticotropin-releasing hormone neurons of the paraventricular hypothalamic nucleus

ObjectiveThis study investigates the sleep-modulating effects of ginsenoside Rg1 (Rg1, C42H72O14), a key bioactive component of ginseng, and elucidates its underlying mechanisms. MethodsC57BL/6J mice were intraperitoneally administered doses of Rg1 ranging from 12.5 to 100 mg/kg. Sleep parameters were assessed to determine the average duration of each sleep stage by monitoring the electrical activity of the brain and muscles. Further, orexin neurons in the lateral hypothalamus (LH) and corticotropin-releasing hormone (CRH) neurons in the paraventricular hypothalamic nucleus (PVH) were ablated using viral vector surgery and electrode embedding. The excitability of LHorexin and PVHCRH neurons was evaluated through the measurement of cellular Finkel-Biskis-Jinkins murine osteosarcoma viral oncogene homolog (c-Fos) expression. ResultsRg1 (12.5–100 mg/kg) augmented the duration of non-rapid eye movement (NREM) sleep phases, while reducing the duration of wakefulness, in a dose dependent manner. The reduced latency from wakefulness to NREM sleep indicates an accelerated sleep initiation time. We found that these sleep-promoting effects were weakened in the LHorexin and PVHCRH neuron ablation groups, and disappeared in the orexin and CRH double-ablation group. Decreased c-Fos protein expression in the LH and PVH confirmed that Rg1 promoted NREM sleep by inhibiting orexin and CRH neurons. ConclusionRg1 increases the duration of NREM sleep, underscoring the essential roles of LHorexin and PVHCRH neurons in facilitating the sleep-promoting effects of Rg1.

Modulation of Hypothalamic Dopamine Neuron Activity by Interaction Between Caloric State and Amphetamine in Zebrafish Larvae.

Dopamine (DA) signaling is evoked by both food and drugs that humans come to abuse. Moreover, physiological state (e.g., hunger versus satiety) can modulate the response. However, there is great heterogeneity among DA neurons. Limited studies have been performed that could resolve the interaction between physiological state and drug responsivity across groups of DA neurons. Here, we measured the activity of neurons in transgenic Tg (th2:GCaMP7s) zebrafish larva that expresses a calcium indicator (GCaMP7s) in A11 (posterior tuberculum) and a part of A14 (caudal hypothalamus and intermediate hypothalamus) DA populations located in the hypothalamus of the larval zebrafish. Fish were recorded in one of two physiological states: ad-libitum fed (AL) and food deprived (FD) and before and after acute exposure to different doses of the stimulant drug amphetamine (0, 0.7, and 1.5 μM). We quantified fluorescence change, activity duration, peak rise/fall time, and latency in the calcium spikes of the DA neurons. Our results show that baseline DA neuron activity amplitude, spike duration, and correlation between inter- and intra-DA neurons were higher in the FD than in the AL state. Dose-dependent AMPH treatment further increased the intensity of these parameters in the neuron spikes but only in the FD state. The DA activity correlation relatively increased in AL state post-AMPH treatment. Given that hunger increases drug reactivity and the probability of relapse to drug seeking, the results support populations of DA neurons as potential critical mediators of the interaction between physiological state and drug reinforcement.

A β-hydroxybutyrate shunt pathway generates anti-obesity ketone metabolites.

β-Hydroxybutyrate (BHB) is an abundant ketone body. To date, all known pathways of BHB metabolism involve the interconversion of BHB and primary energy intermediates. Here, we identify a previously undescribed BHB secondary metabolic pathway via CNDP2-dependent enzymatic conjugation of BHB and free amino acids. This BHB shunt pathway generates a family of anti-obesity ketone metabolites, the BHB-amino acids. Genetic ablation of CNDP2 in mice eliminates tissue amino acid BHB-ylation activity and reduces BHB-amino acid levels. The most abundant BHB-amino acid, BHB-Phe, is a ketosis-inducible congener of Lac-Phe that activates hypothalamic and brainstem neurons and suppresses feeding. Conversely, CNDP2-KO mice exhibit increased food intake and body weight following exogenous ketone ester supplementation or a ketogenic diet. CNDP2-dependent amino acid BHB-ylation and BHB-amino acid metabolites are also conserved in humans. Therefore, enzymatic amino acid BHB-ylation defines a ketone shunt pathway and bioactive ketone metabolites linked to energy balance.

Orexinergic modulation of chronic jet lag-induced deficits in mouse cognitive flexibility.

Cognitive flexibility and working memory are important executive functions mediated by the prefrontal cortex and can be impaired by circadian rhythm disturbances such as chronic jet lag (CJL) or shift work. In the present study, we used mice to investigate whether (1) simulated CJL impairs cognitive flexibility, (2) the orexin system is involved in such impairment, and (3) nasal administration of orexin A is able to reverse CJL-induced deficits in cognitive flexibility and working memory. Mice were exposed to either standard light-dark conditions or simulated CJL consisting of series of advance time shifts. Experiment (1) investigated the effects of a mild CJL protocol on cognitive flexibility using the attentional set shifting task. Experiment (2) used a stronger CJL protocol and examined CJL effects on the orexin system utilizing c-Fos and orexin immunohistochemistry. Experiment (3) tested whether nasal orexin application can rescue CJL-induced deficits in cognitive flexibility and working memory, the latter by measuring spontaneous alternation in the Y-maze. The present data show that CJL (1) impairs cognitive flexibility and (2) reduces the activity of orexin neurons in the lateral hypothalamus. (3) Nasal administration of orexin A rescued CJL-induced deficits in working memory and cognitive flexibility. These findings suggest that executive function impairments by circadian rhythm disturbances such as CJL are caused by dysregulation of orexinergic input to the prefrontal cortex. Compensation of decreased orexinergic input by nasal administration of orexin A could be a potential therapy for CJL- or shift work-induced human deficits in executive functions.

Regulation of wakefulness by neurotensin neurons in the lateral hypothalamus

The lateral hypothalamic region (LH) has been identified as a key region for arousal regulation, yet the specific cell types and underlying mechanisms are not fully understood. While neurons expressing orexins (OX) are considered the primary wake-promoting population in the LH, their loss does not reduce daily wake levels, suggesting the presence of additional wake-promoting populations. In this regard, we recently discovered that a non-OX cell group in the LH, marked by the expression of neurotensin (Nts), could powerfully drive wakefulness. Activation of these NtsLH neurons elicits rapid arousal from non-rapid eye movement (NREM) sleep and produces uninterrupted wakefulness for several hours in mice. However, it remains unknown if these neurons are necessary for spontaneous wakefulness and what their precise role is in the initiation and maintenance of this state. To address these questions, we first examined the activity dynamics of the NtsLH population across sleep-wake behavior using fiber photometry. We find that NtsLH neurons are more active during wakefulness, and their activity increases concurrently with, but does not precede, wake-onset. We then selectively destroyed the NtsLH neurons using a diphtheria-toxin-based conditional ablation method, which significantly reduced wake amounts and mean duration of wake bouts and increased the EEG delta power during wakefulness. These findings demonstrate a crucial role for NtsLH neurons in maintaining normal arousal levels, and their loss may be associated with chronic sleepiness in mice.

Konjac glucomannan Inhibits Appetite of Obese Mice by Suppressing Hypothalamic Inflammatory Response and Agrp/Npy Neuron Expression.

Konjac glucomannan (KGM) is used for appetite management. However, KGM's regulation of appetite through hypothalamic neurons and gut microbiota, particularly in nonobese populations, is required to be investigated. This study investigated the differential effects of KGM on appetite and energy metabolism in obese and nonobese mice. In obese mice, KGM inhibited food intake, hypothalamic inflammation, and increased energy expenditure. Conversely, in nonobese mice, KGM maintained food intake and energy expenditure but increased hypothalamic inflammation. KGM downregulated hypothalamic Agrp, Npy, and Orx expression and upregulated Cart in obese mice, while it had no effect on orexigenic genes and downregulated Cart in nonobese mice. Additionally, KGM reshaped gut microbiota and increased Short-chain fatty acids (SCFAs) formation of obese mice, where Alistipes, Bifidobacterium, and Lactobacillus, as well as SCFAs, correlated with suppressed appetite. In nonobese mice, KGM has no significant effect on SCFAs but microbes such as Blautia, Alistipes, and Flavonifractor levels were negatively correlated with hypothalamic inflammation. KGM maintains appetite and was linked to liver-derived phosphatidylcholine, countering increased hypothalamic inflammation. The differential regulation of appetite by KGM between obese and nonobese mice is associated with hypothalamic inflammatory, neuronal, and KGM-induced personalized reshaping of gut microbiota. KGM may regulate energy intake and expenditure through the microbiota-gut-brain axis.

Chronic olanzapine treatment leads to increased opioid receptor expression and changes in feeding regulating neurons in the female rat hypothalamus

Opioid receptor antagonists have shown increasing promise as an adjunct therapy to psychotropic medication. The goal is to reduce the weight gain and metabolic adverse effects that are associated with certain second-generation antipsychotics, such as olanzapine and clozapine. In this study, female rats were treated for 4 weeks with a long-acting injectable formulation of olanzapine to assess effects on hypothalamic feeding regulation. Using quantitative spatial in situ hybridization and receptor autoradiography, expression levels of the mu, kappa and delta opioid receptors were defined in the five hypothalamic areas: paraventricular nucleus (PVN), arcuate nucleus (ARC), ventromedial nucleus (VMN), dorsomedial nucleus (DMN) and lateral hypothalamus (LH). In addition, hypothalamic neuron number and size were estimated using the unbiased optical fractionator and spatial rotator methods. Hyperphagia was observed after only 24 hours of olanzapine treatment, with continued weight gain throughout the duration of the study. In contrast, the observed food intake reversed to control levels after 2 weeks of olanzapine treatment. Chronic olanzapine treatment increased expression of kappa opioid receptor mRNA and receptor availability in the PVN, as well as increased mu opioid receptor availability in the PVN, ARC and VMN. These changes were accompanied by fewer anorexigenic proopiomelanocortin-expressing neurons of the ARC and corticotropin-releasing hormone expressing neurons of the PVN. This study links olanzapine-driven metabolic effects to increased opioid receptor expression in the hypothalamus, thus providing a rationale for the positive effects of using opioid receptor antagonists to relieve olanzapine adverse effects.

KCNB1-Leptin receptor complexes couple electric and endocrine function in the melanocortin neurons of the hypothalamus.

The neurons of the melanocortin system regulate feeding and energy homeostasis through a combination of electrical and endocrine mechanisms. However, the molecular basis for this functional heterogeneity is poorly understood. Here, a voltage-gated potassium (Kv+) channel named KCNB1 (alias Kv2.1) forms stable complexes with the leptin receptor (LepR) in a subset of hypothalamic neurons including proopiomelanocortin (POMC) expressing neurons of the Arcuate nucleus (ARHPOMC). Mice lacking functional KCNB1 channels (NULL mice) have less adipose tissue and circulating leptin than WT animals and are insensitive to anorexic stimuli induced by leptin administration. NULL mice produce aberrant amounts of POMC at any developmental stage. Canonical LepR-STAT3 signaling-which underlies POMC production-is impaired, whereas non-canonical insulin receptor substrate PI3K/Akt/FOXO1 and ERK signaling are constitutively upregulated in NULL hypothalami. The levels of proto-oncogene c-Fos-that provides an indirect measure of neuronal activity-are higher in arcuate NULL neurons compared to WT and most importantly do not increase in the former upon leptin stimulation. Hence, a Kv channel provides a molecular link between neuronal excitability and endocrine function in hypothalamic neurons.

Spatial mRNA expression patterns of orexin receptors in the dorsal hippocampus.

Orexins are wake-promoting neuropeptides that originate from hypothalamic neurons projecting to widespread brain areas throughout the central nervous system. They modulate various physiological functions via their orexin 1 (OXR1) and 2 (OXR2) receptors, including sleep-wake rhythm but also cognitive functions such as memory formation. Here, we provide a detailed analysis of OXR1 and OXR2 mRNA expression profiles in the dorsal hippocampus as a key region for memory formation, using RNAscope multiplex in situ hybridization. Interconnected subareas relevant for cognition and memory such as the medial prefrontal cortex and the nucleus reuniens of the thalamus were assessed as well. Both receptor types display distinct profiles, with the highest percentage of OXR1 mRNA-positive cells in the hilus of the dentate gyrus. Here, the content of OXR1 mRNA per cell was slightly modulated at selected time points over a 12h light/ 12 dark light phase. Using RNAScope and quantitative polymerase chain reaction approaches, we began to address a cell-type specific expression of OXR1 in hilar GABAergic interneurons. The distinct expression profiles of both receptor subtypes within hippocampal subareas and circuits provide an interesting basis for future interventional studies on orexin receptor function in spatial and contextual memory.

A hypothalamic circuit mechanism underlying the impact of stress on memory and sleep.

Stress profoundly affects sleep and memory processes. Stress impairs memory consolidation, and similarly, disruptions in sleep compromise memory functions. Yet, the neural circuits underlying stress-induced sleep and memory disturbances are still not fully understood. Here, we show that activation of CRHPVN neurons, similar to acute restraint stress, decreases sleep and impairs memory in a spatial object recognition task. Conversely, inhibiting CRHPVN neurons during stress reverses stress-induced memory deficits while slightly increasing the amount of sleep. We found that both stress and stimulation of CRHPVN neurons activate neurons in the lateral hypothalamus (LH), and that their projections to the LH are critical for mediating stress-induced memory deficits and sleep disruptions. Our results suggest a pivotal role for CRHPVN neuronal pathways in regulating the adverse effects of stress on memory and sleep, an important step towards improving sleep and ameliorating the cognitive deficits that occur in stress-related disorders.

Functionally Separate Populations of Ventromedial Hypothalamic Neurons in Obesity and Diabetes.

The Ventromedial hypothalamic nucleus (VMN) maintains healthy metabolic function through several important roles. Collectively, homeostasis is maintained via intermingled cells within the VMN that raise blood glucose, lower blood glucose, and stimulate energy expenditure when needed. This perspective discusses the defining factors for the VMN cell types that govern distinct functions induced by the VMN, particularly in relation to energy balance and blood glucose levels. Special attention is given to distinct features of VMN cells responsible for these processes. Finally, these topics are reviewed in the context of research funded by the Pathway to Stop Diabetes initiative, highlighting key findings and current unresolved questions for future investigations.