Hypothalamic Centers Research Articles

Clinical Analysis of Resemblance and Dissimilarities of Glucagon-like Peptide-1 Receptor Agonists: Therapeutic Approach Towards the Management of Diabetes Mellitus

Abstract: One of the classes of injective antidiabetic agents includes Glucagon-like peptide-1 receptor agonists (GLP-1RA) which ameliorate glycemia and numerous atherosclerosis-related factors in individuals prone to Type 2 diabetes mellitus (T2-DM) disorder. Methods: The review paper targeted the role of GLP-1RA in managing DM. The literature published during the last decades in several data-based searches (PubMed, Scopus, ScienceDirect) was reviewed and compiled the therapeutic uses of GLP-1 RA in the management of DM. In this review, we have discussed GLP-1RA and its role in the management of diabetes mellitus. Results and Discussion: Disrupted homeostasis marks insulin resistance and β-cell deterioration as two major indications of T2-DM. β-cells failure (~80% of functioning of β-cell) and insulin resistance in the liver and muscles are primarily susceptive to physiological defects. GLP-1RAs if administered for a prolonged period also cause a loss in weight through the activation of receptors of GLP-1 found in hypothalamic satiety centers which control appetite and decrease intake of calories. They not only assist in controlling blood glucose but also improve β- cell function and post–diabetic conditions namely hyperlipidemia, obesity, and hypertension. Conclusion: It was concluded that GLP-1RA has a new therapeutic approach to the management of DM. Hence, GLP-1RA provides distinctive and innovative evolution for the treatment of T2-DM.

Neurobiology of Sweet Cravings: The Brain’s Reward System Response to Hedonic Eating

Background: Energy homeostasis is not an easy algebraic sum of energy intake and energy spending, where it is a dynamic process affected by affects by the relation between energy expenditure and food intake. By complex nervous system including the hypothalamic centers and peripheral satiety system the energy homeostasis is controlled. Peripheral satiety mechanisms released peptides and hormones which in turn regulate metabolism or impacts on satiation. Sweet foods have high calories disrupts appetite regulation and induce the pleasure and reward system, so, it count to be an main source of stimulation that may leads to overeat and contribute to the evolution of the obesity. Sweet foods consume impact on hunger-satiety mechanism, assisting starting of consumption in absence of energy needs and keeping of feeding in spite of intake of huge food loads that risk homeostasis. consumption of too much amounts of sweet foods depend on mechanisms that advance behaviors addictive-like, and on bypassing the neuroendocrine cues that protect inner environment.

Investigating the Molecular Mechanisms of Lysine’s Effect on Feed Intake in Chicks Through the Hypothalamus using RNA-seq and Metabolomics

Background: There is a current lack of research on the molecular pathways by which lysine regulates feed intake in chicks. Regulation is controlled by the hypothalamus and lysine metabolism links the availability of amino acids and nutritional perception with food intake. The mechanism underlying this phenomenon remains unclear. To investigate the regulatory mechanism of lysine on feed intake in chicks, this study used Yao chickens as a research model. The levels of lysine in the feed of chicks were adjusted to determine the effect on feed intake. The hypothalamus tissue of the chicks was analyzed using RNA-seq and metabolomics to identify the relevant genes. We employed Gene Ontology and identification of signaling pathways to characterize the molecular regulatory biological pathways of lysine in poultry feeding. Methods: This study used RNA-seq technology to investigate the genes and marker metabolites involved in lysine regulation of feed intake in chickens. The study explored the molecular mechanism by which dietary lysine regulates feed intake in chickens via the hypothalamus. Four hundred healthy 1-day-old chicks (Yao chickens) were randomly divided into four groups, with five replicates in each group (n = 20). Result: There was a significant difference in feed intake among chicks fed with diets containing 0.65% (abbreviated as MGO), 0.85% (FIH), 1.0% (MGS) and 1.2% (FIL) lysine levels. The group with the highest feed intake was FIH, while the group with the lowest feed intake was FIL. By conducting RNA-seq of the hypothalamic tissue of chickens in both the highest and lowest feed intake groups, we obtained 2006 differentially expressed genes, comprising 1275 upregulated genes and 731 downregulated genes. Fourteen genes were related to food intake, including growth hormone, recombinant glutamate receptor, metabotropic 1 (GRM1) and recombinant glutamate receptor, metabotropic 3 (GRM3). Using liquid chromatograph mass spectrometer (LC-MS) metabolomics, we identified 25 differential metabolites. Nine metabolites, including C3H5NO4, C10H15NO2 and C13H14N203, were downregulated, while 16 metabolites, including C2H8NO3P, C3H7NO3 and C7H7NO2, were upregulated. Marker metabolites included 5-hydroxytryptophan and L-valine. A KEGG enrichment analysis revealed that the differential metabolites between the FIH and FIL groups were enriched in 26 pathways, with the significantly enriched pathway being the ABC transporter protein pathway (ID: map02010). RNA-seq and LC-MS analyses revealed that in chicks, the expression of the neuropeptides cocaine- and Amphetamine-Regulated Transcript Protein (CARTPT) and neuropeptide Y (NPY)/agouti-related protein (AGRP), along with genes such as sucrose synthase (SS 2), recombinant cholecystokinin A receptor (CCKAR) and recombinant cholecystokinin B receptor (CCKBR), was regulated by the hypothalamic feeding regulation center that senses the level of lysine in the feed. These molecules bind to specific receptors and initiate a signaling cascade in specific hypothalamic neuronal groups, thereby regulating chick feed intake and in turn affecting growth, development and production performance.

The gut microbiota-derived metabolite indole-3-propionic acid enhances leptin sensitivity by targeting STAT3 against diet-induced obesity.

Obesity is associated with the gut microbiome. Here, we report that gut commensal Clostridia bacteria regulate host energy balance through the tryptophan-derived metabolite indole-3-propionic acid (IPA). IPA acts as an endogenous leptin sensitiser to counteract obesity. Mechanistically, IPA is secreted from the gut into the circulation, and then targets to the STAT3 in the hypothalamic appetite regulation centre, promoting its phosphorylation and nuclear translocation, which enhances the body's response to leptin, and regulates the balance between appetite and energy metabolism. The in vitro pull-down assays involving site-directed mutagenesis demonstrate that Trp623 in the SH2 domain is the key binding site for STAT3-IPA interaction. High-fat diet (HFD), rather than genetic factors, induces excessive secretion of antimicrobial peptides by Paneth cells, inhibiting the growth of Clostridia in the gut and resulting in decreased production of the beneficial metabolite IPA. IPA or Clostridium sporogenes supplement effectively controls weight gain, improves glucose metabolism, and reduces inflammation in DIO mice. IPA fails to achieve such effects in ob/ob mice, while exogenous leptin administration restores the therapeutic effect of IPA. Our study suggests that the IPA-based gut-brain axis regulates host metabolism, and supplementation with microbiome-derived IPA could be a promising intervention strategy for treating obesity.

Endocrine-Disrupting Chemicals, Hypothalamic Inflammation and Reproductive Outcomes: A Review of the Literature.

Endocrine-disrupting chemicals (EDCs) are environmental and industrial agents that interfere with hormonal functions. EDC exposure is linked to various endocrine diseases, especially in reproduction, although the mechanisms remain unclear and effects vary among individuals. Neuroinflammation, particularly hypothalamic inflammation, is an emerging research area with implications for endocrine-related diseases like obesity. The hypothalamus plays a crucial role in regulating reproduction, and its inflammation can adversely affect reproductive health. EDCs can cross the blood-brain barrier, potentially causing hypothalamic inflammation and disrupting the reproductive axis. This review examines the existing literature on EDC-mediated hypothalamic inflammation. Our findings suggest that exposure to 2,3,7,8-tetrachloro-dibenzo-p-dioxin (TCDD), polychlorinated biphenyl (PCB), tributyltin (TBT), phthalates, bisphenol A (BPA), and chlorpyrifos (CPF) in animals is linked to hypothalamic inflammation, specifically affecting the hypothalamic centers of the gonadotropic axis. To our knowledge, this is the first comprehensive review on this topic, indicating hypothalamic inflammation as a possible mediator between EDC exposure and reproductive dysfunction. Further human studies are needed to develop effective prevention and treatment strategies against EDC exposure.

Selective vulnerability of parvocellular oxytocin neurons in social dysfunction

Selective vulnerability offers a conceptual framework for understanding neurodegenerative disorders such as Parkinson’s disease, where specific neuronal types are selectively affected and adjacent ones are spared. However, the applicability of this framework to neurodevelopmental disorders, particularly those characterized by atypical social behaviors, such as autism spectrum disorder, remains uncertain. Here we show that an embryonic disturbance, known to induce social dysfunction in male mice, preferentially impaired the gene expression crucial for neural functions in parvocellular oxytocin (OT) neurons—a subtype linked to social rewards—while neighboring cell types experienced a lesser impact. Chemogenetic stimulation of OT neurons at the neonatal stage ameliorated social deficits in early adulthood, concurrent with cell-type-specific sustained recovery of pivotal gene expression within parvocellular OT neurons. Collectively, our data shed light on the transcriptomic selective vulnerability within the hypothalamic social behavioral center and provide a potential therapeutic target through specific neonatal neurostimulation.

Maternal diet during pregnancy and adaptive changes in the maternal and fetal pancreas have implications for future metabolic health.

Fetal and neonatal development is a critical period for the establishment of the future metabolic health and disease risk of an individual. Both maternal undernutrition and overnutrition can result in abnormal fetal organ development resulting in inappropriate birth size, child and adult obesity, and increased risk of Type 2 diabetes and cardiovascular diseases. Inappropriate adaptive changes to the maternal pancreas, placental function, and the development of the fetal pancreas in response to nutritional stress during pregnancy are major contributors to a risk trajectory in the offspring. This interconnected maternal-placental-fetal metabolic axis is driven by endocrine signals in response to the availability of nutritional metabolites and can result in cellular stress and premature aging in fetal tissues and the inappropriate expression of key genes involved in metabolic control as a result of long-lasting epigenetic changes. Such changes result is insufficient pancreatic beta-cell mass and function, reduced insulin sensitivity in target tissues such as liver and white adipose and altered development of hypothalamic satiety centres and in basal glucocorticoid levels. Whilst interventions in the obese mother such as dieting and increased exercise, or treatment with insulin or metformin in mothers who develop gestational diabetes, can improve metabolic control and reduce the risk of a large-for-gestational age infant, their effectiveness in changing the adverse metabolic trajectory in the child is as yet unclear.

A Century of Prolactin: Emerging Perspectives as a Metabolic Regulator.

Prolactin, a hormone that has been studied for almost a century, has evolved from a reproductive regulator to a key player in metabolic health. Initially identified for its lactogenic role, the impact of prolactin on glucose and lipid metabolism became evident in the 1970s, leading to a paradigm shift in our understanding. Deviations in prolactin levels, including hyperprolactinaemia and hypoprolactinaemia, have been associated with adverse effects on glucose and lipid metabolism. Mechanistically, prolactin regulates metabolic homoeostasis by maintaining islet abundance, regulating the hypothalamic energy regulatory centre, balancing adipose tissue expansion, and regulating hepatic metabolism. Given the widespread use of pharmaceutical agents that affect prolactin levels, it is important to examine prolactin-related metabolic effects. Recently, a profound exploration of the intricate metabolic role of prolactin has been conducted, encompassing its rhythm-dependent regulatory influence on metabolism and its correlation with cognitive impairment associated with metabolic diseases. In this review, we highlight the role of prolactin as a metabolic regulator, summarise its metabolic effects, and discuss topics related to the association between prolactin and metabolic comorbidities.

Hypothalamic hormone deficiency enables physiological anorexia in ground squirrels during hibernation

Mammalian hibernators survive prolonged periods of cold and resource scarcity by temporarily modulating normal physiological functions, but the mechanisms underlying these adaptations are poorly understood. The hibernation cycle of thirteen-lined ground squirrels (Ictidomys tridecemlineatus) lasts for 5–7 months and comprises weeks of hypometabolic, hypothermic torpor interspersed with 24–48-h periods of an active-like interbout arousal (IBA) state. We show that ground squirrels, who endure the entire hibernation season without food, have negligible hunger during IBAs. These squirrels exhibit reversible inhibition of the hypothalamic feeding center, such that hypothalamic arcuate nucleus neurons exhibit reduced sensitivity to the orexigenic and anorexigenic effects of ghrelin and leptin, respectively. However, hypothalamic infusion of thyroid hormone during an IBA is sufficient to rescue hibernation anorexia. Our results reveal that thyroid hormone deficiency underlies hibernation anorexia and demonstrate the functional flexibility of the hypothalamic feeding center.

Microglia mediate the early-life programming of adult glucose control.

Mammalian glucose homeostasis is, in part, nutritionally programmed during early neonatal life, a critical window for the formation of synapses between hypothalamic glucoregulatory centers. Although microglia are known to prune synapses throughout the brain, their specific role in refining hypothalamic glucoregulatory circuits remains unknown. Here, we show that microglia in the mediobasal hypothalamus (MBH) of mice actively engage in synaptic pruning during early life. Microglial phagocytic activity is induced following birth, regresses upon weaning from maternal milk, and is exacerbated by feeding dams a high-fat diet while lactating. In particular, we show that microglia refine perineuronal nets (PNNs) within the neonatal MBH. Indeed, transiently depleting microglia before weaning (P6-16), but not afterward (P21-31), remarkably increased PNN abundance in the MBH. Furthermore, mice lacking microglia only from P6-16 had glucose intolerance due to impaired glucose-responsive pancreatic insulin secretion in adulthood, a phenotype not seen if microglial depletion occurred after weaning. Viral retrograde tracing revealed that this impairment is linked to a reduction in the number of neurons in specific hypothalamic glucoregulatory centers that synaptically connect to the pancreatic β-cell compartment. These findings show that microglia facilitate synaptic plasticity in the MBH during early life through a process that includes PNN refinement, to establish hypothalamic circuits that regulate adult glucose homeostasis.

A descending pathway from the lateral/ventrolateral PAG to the rostroventral medulla mediating the vasomotor response evoked by social defeat stress in rats.

The stress-induced cardiovascular response is based on the defensive reaction in mammals. It has been shown that the sympathetic vasomotor pathway of acute psychological stress is indirectly mediated via neurons in the rostroventral medulla (RVM) from the hypothalamic stress center. In this study, direct projections to the RVM and distribution of neuroexcitatory marker c-Fos-expressed neurons were investigated during social defeat stress (SDS) in conscious rats. The experimental rat that was injected with a neural tracer, FluoroGold (FG) into the unilateral RVM, was exposed to the SDS. Double-positive neurons of both c-Fos and FG were locally distributed in the lateral/ventrolateral periaqueductal gray matter (l/vl PAG) in the midbrain. These results suggest that the neurons in the l/vl PAG contribute to the defensive reaction evoked by acute psychological stress, such as the SDS. During the SDS period, arterial pressure (AP) and heart rate (HR) showed sustained increases in the rat. Therefore, we performed chemical stimulation by excitatory amino acid microinjection within the l/vl PAG and measured cardiovascular response and sympathetic nerve activity in some anesthetized rats. The chemical stimulation of neurons in the l/vl PAG caused significant increases in arterial pressure and renal sympathetic nerve activity. Taken together, our results suggest that neurons in the l/vl PAG are a possible candidate for the cardiovascular descending pathway that modulates sympathetic vascular resistance evoked by acute psychological stress, like the SDS.NEW & NOTEWORTHY The sympathetic vasomotor pathway of an acute psychological stress-induced cardiovascular response is mediated via neurons in the RVM indirectly from the hypothalamus. In this study, we showed the relaying area of the efferent sympathetic vasomotor pathway from the hypothalamus to the RVM. The results suggested that the pressor response during psychological stress is mediated via neurons in the lateral/ventrolateral PAG to the RVM.

QRFP43 modulates the activity of the hypothalamic appetite regulatory centre in sheep

QRFP43 modulates the activity of the hypothalamic appetite regulatory centre in sheep

FDA approved fezolinetant (Veozah): a critical evaluation of its efficacy and safety for menopausal vasomotor symptoms, calling for prospective research.

Women going through menopause frequently experience vasomotor symptoms such as hot flashes, night sweats, and sleep disturbances, significantly influencing their quality of life. Hormonal therapy has been demonstrated to be beneficial in treating VMS. However, due to specific restrictions, it is not recommended for every woman. Fezolinetant, a neurokinin 3 antagonist and non-hormonal treatment for severe to moderate VMS, functions by inhibiting neuronal impulses originating from the hypothalamic thermoregulatory center. Current Skylight 2 and 4 trials statistically demonstrate the safety and acceptability of fezolinetant, with relatively few adverse effects reported. Fezolinetant has been shown great potential for treating menopausal-related VMS, supporting its further advancement. However, further investigation is required to thoroughly evaluate its safety, effectiveness, and its impact on sleep patterns.

Maternal inulin alleviates high-fat diet-induced lipid disorder in offspring by epigenetically modulating hypothalamus feeding circuit-related genes.

Increasing evidence supports the existence of fetal-originated adult diseases. Recent research indicates that the intrauterine environment affects the fetal hypothalamic energy intake center. Inulin is a probiotic that can moderate metabolic disorders, but whether maternal inulin intervention confers long-term metabolic benefits to lipid metabolism in offspring in their adult lives and the mechanism involved are unknown. Here, we used a maternal overnutrition model that was induced by excess energy intake before and during pregnancy and lactation and maternal inulin intervention was performed during pregnancy and lactation. The hypothalamic genome methylation in offspring was analyzed using a methylation array. The results showed that maternal inulin treatment modified the maternal high-fat diet (HFD)-induced increases in body weight, adipose tissue weight, and serum insulin and leptin levels and decreases in serum adiponectin levels. Maternal inulin intervention regulated the impairments in hypothalamic leptin resistance, induced the methylation of Socs3, Npy, and Il6, and inhibited the methylation of Lepr in the hypothalamus of offspring. In conclusion, maternal inulin intervention modifies offspring lipid metabolism, and the underlying mechanism involves the methylation of genes in the hypothalamus feeding circuit.

DNA Methylation in the Hypothalamic Feeding Center and Obesity.

Obesity rates have been increasing worldwide for decades, mainly due to environmental factors, such as diet, nutrition, and exercise. However, the molecular mechanisms through which environmental factors induce obesity remain unclear. Several mechanisms underlie the body's response to environmental factors, and one of the main mechanisms involves epigenetic modifications, such as DNA methylation. The pattern of DNA methylation is influenced by environmental factors, and altered DNA methylation patterns can affect gene expression profiles and phenotypes. DNA methylation may mediate the development of obesity caused by environmental factors. Similar to the factors governing obesity, DNA methylation is influenced by nutrients and metabolites. Notably, DNA methylation is associated with body size and weight programming. The DNA methylation levels of proopiomelanocortin (Pomc) and neuropeptide Y (Npy) in the hypothalamic feeding center, a key region controlling systemic energy balance, are affected by diet. Conditional knockout mouse studies of epigenetic enzymes have shown that DNA methylation in the hypothalamic feeding center plays an indispensable role in energy homeostasis. In this review, we discuss the role of DNA methylation in the hypothalamic feeding center as a potential mechanism underlying the development of obesity induced by environmental factors.

Glial cell changes in the corpus callosum in chronically-starved mice

Anorexia nervosa (AN) is characterized by emaciation, hyperactivity, and amenorrhea. Imaging studies in AN patients have revealed reductions in grey and white matter volume, which correlate with the severity of neuropsychological deficits. However, the cellular basis for the observed brain atrophy is poorly understood. Although distinct hypothalamic centers, including the arcuate nucleus (ARC) are critically involved in regulating feeding behavior, little is known about potential hypothalamic modifications in this disorder. Since glia e.g. astrocytes and microglia influence neuronal circuits, we investigated the glial changes underlying pathophysiology of starvation in the corpus callosum (CC) and hypothalamus. Female mice were given a limited amount of food once a day and had unlimited access to a running wheel until a 20% weight reduction was achieved (acute starvation). This weight reduction was maintained for two weeks to mimic chronic starvation. Immunohistochemistry was used to quantify the density of astrocytes, microglia, oligodendrocytes, and the staining intensity of neuropeptide Y (NPY), a potent orexigenic peptide. Chronic starvation induced a decreased density of OLIG2+ oligodendrocytes, GFAP+ astrocytes, and IBA1+ microglia in the CC. However, the densities of glial cells remained unchanged in the ARC following starvation. Additionally, the staining intensity of NPY increased after both acute and chronic starvation, indicating an increased orexigenic signaling. Chronic starvation induced glial cell changes in the CC in a mouse model of AN suggesting that glia pathophysiology may play a role in the disease.

24 Effects of Gestational and Postweaning Nutrition on Brain Development and Puberty in Beef Heifers

Abstract Approximately 5 million beef heifers enter the U.S. cow herd annually, and their lifetime productivity is largely dependent upon their ability to attain puberty and produce a calf by 24 mo of age. However, a considerable proportion of heifers within existing U.S. production systems fail to achieve these goals, particularly in southern regions where Bos indicus-influenced cattle predominate. Consequently, managerial approaches are needed that employ nutritional programming of the reproductive neuroendocrine axis, while minimizing feeding costs and optimizing the consistent attainment of puberty by approximately 14 mo of age. Our previous research has clearly demonstrated that increased BW gain between 4 and 8 mo of age facilitates pubertal development by programming hypothalamic centers that regulate gonadotropin releasing-hormone (GnRH) secretion. Among the different metabolic hormones, leptin has a critical role in conveying nutritional information to the hypothalamus and controlling puberty. Two hypothalamic neuronal populations that express the orexigenic peptide neuropeptide Y (NPY) and the anorexigenic peptide alpha melanocyte-stimulating hormone (αMSH; a product of the POMC gene) are key components of afferent pathways that convey inhibitory (NPY) and excitatory (αMSH) inputs to GnRH and kisspeptin neurons. Our studies have demonstrated that short-term increases in dietary energy intake after early weaning at 4 mo of age result in epigenetic, structural, and functional modifications in these hypothalamic pathways to promote high-frequency, episodic release of GnRH and luteinizing hormone. However, integrating the foundational knowledge of metabolic imprinting of the brain for early puberty with issues related to lifetime performance is complex. One approach has been to employ a novel stair-step nutritional regimen involving alternating periods of dietary energy-restriction and re-feeding during juvenile development. This approach is designed to support early onset of puberty by imprinting functional alterations in the hypothalamus during key periods of brain development while optimizing other aspects of growth and performance. Finally, while several key processes of fetal brain development occur during late gestation, neither maternal undernutrition (BCS 3.0-3.5) nor maternal obesity (BCS 7.5-8.0) during the last two trimesters of gestation impacted the organization of hypothalamic neurocircuitries controlling GnRH/LH secretion or age at puberty in the heifer offspring. Collectively, these results indicate that the adult reproductive phenotype in Bos indicus-influenced females is resilient to significant degrees of nutritional stress imposed during prenatal development, particularly if early gestation (first trimester) is avoided. These findings are in contrast with reports in Bos taurus females in which late gestation nutritional extremes result in delayed puberty in heifer offspring, suggesting that potential genotype-specific differences may exist. Research support: USDA-NIFA-AFRI (2018-67015-27595 and 2021-67015-33676).

Paracetamol and ibuprofen in the treatment of pain and fever in children: modern views on the choice of a drug

Paracetamol (acetaminophen) and ibuprofen are commonly used to relieve fever and pain in children. Their effects are similar, but differ in strength and mechanisms of action on the body. Acetaminophen, a para-aminophenol derivative, has antipyretic and analgesic properties. Despite the fact that paracetamol has been officially used as a drug for more than 75 years, its mechanism of biological action has not been sufficiently studied. In paediatric practice, paracetamol is more often used as an antipyretic, but in recent years, with the development of technology and emergence of new dosage forms on the market, it came into common use as an analgesic in many diseases, including oncological, rheumatological, etc. Ibuprofen is the most commonly used non-steroidal anti-inflammatory drug with pronounced analgesic and antipyretic properties. Ibuprofen, a non-selective inhibitor of cyclooxygenase-1 (COX-1) and cyclooxygenase-2 (COX-2), affects the hypothalamic thermoregulatory center via inhibition of prostaglandin synthesis. In the paediatric population, the most common indications for the use of ibuprofen are fever, sore throat, ear pain, headache and toothache, post-traumatic and musculoskeletal pain, and inflammatory joint diseases. Paracetamol and ibuprofen are safe for use in paediatric practice, if dosing rules are observed, and are approved for use by the World Health Organization, FDA and other expert organizations. In addition, the emergence of new presentation forms of these drugs is most important in paediatrics.

Synaptic plasticity and the role of astrocytes in central metabolic circuits.

Neural circuits in the brain, primarily in the hypothalamus, are paramount to the homeostatic control of feeding and energy utilization. They integrate hunger, satiety, and body adiposity cues from the periphery and mediate the appropriate behavioral and physiological responses to satisfy the energy demands of the animal. Notably, perturbations in central homeostatic circuits have been linked to the etiology of excessive feeding and obesity. Considering the ever-changing energy requirements of the animal and required adaptations, it is not surprising that brain-feeding circuits remain plastic in adulthood and are subject to changes in synaptic strength as a consequence of nutritional status. Indeed, synapse density, probability of presynaptic transmitter release, and postsynaptic responses in hypothalamic energy balance centers are tailored to behavioral and physiological responses required to sustain survival. Mounting evidence supports key roles of astrocytes facilitating some of this plasticity. Here we discuss these synaptic plasticity mechanisms and the emerging roles of astrocytes influencing energy and glucose balance control in health and disease. This article is categorized under: Cancer > Molecular and Cellular Physiology Neurological Diseases > Molecular and Cellular Physiology.

Maternal emulsifier consumption programs offspring metabolic and neuropsychological health in mice.

Modern lifestyle is associated with a major consumption of ultra-processed foods (UPF) due to their practicality and palatability. The ingestion of emulsifiers, a main additive in UPFs, has been related to gut inflammation, microbiota dysbiosis, adiposity, and obesity. Maternal unbalanced nutritional habits during embryonic and perinatal stages perturb offspring's long-term metabolic health, thus increasing obesity and associated comorbidity risk. However, whether maternal emulsifier consumption influences developmental programming in the offspring remains unknown. Here, we show that, in mice, maternal consumption of dietary emulsifiers (1% carboxymethyl cellulose (CMC) and 1% P80 in drinking water), during gestation and lactation, perturbs the development of hypothalamic energy balance regulation centers of the progeny, leads to metabolic impairments, cognition deficits, and induces anxiety-like traits in a sex-specific manner. Our findings support the notion that maternal consumption of emulsifiers, common additives of UPFs, causes mild metabolic and neuropsychological malprogramming in the progeny. Our data call for nutritional advice during gestation.