Fatty acids as cell signals in ingestive behaviors

Common dietary fatty acids, including palmitic acid, stearic acid, oleic acid, and polyunsaturated fatty acids, have been studied in the context of overall dietary fat and shown to impact on several types of behaviors, most prominently cognitive behaviors and ingestive behaviors. The independent effects of these fatty acids have been less well-delineated. Several studies implicate these common fatty acids in modulation of the CNS immune/inflammatory response as a key mediator of behavioral effects. However, signaling actions of the fatty acids to regulate cell structure and neuronal or synaptic function have been identified in numerous studies, and the relevance or contribution(s) of these to ingestive behavioral outcomes represent an area for future study. Finally, fatty acids are precursors of endocannabinoids and their structural congeners. Being highly dynamic and complex, the endocannabinoid system plays a key role ingestive behavior via cellular and synaptic mechanisms, thus representing another important area for future study

Insulin, leptin, and food reward: update 2008

The hormones insulin and leptin have been demonstrated to act in the central nervous system (CNS) as regulators of energy homeostasis at medial hypothalamic sites. In a previous review, we described new research demonstrating that, in addition to these direct homeostatic actions at the hypothalamus, CNS circuitry that subserves reward and motivation is also a direct and an indirect target for insulin and leptin action. Specifically, insulin and leptin can decrease food reward behaviors and modulate the function of neurotransmitter systems and neural circuitry that mediate food reward, i.e., midbrain dopamine and opioidergic pathways. Here we summarize new behavioral, systems, and cellular evidence in support of this hypothesis and in the context of research into the homeostatic roles of both hormones in the CNS. We discuss some current issues in the field that should provide additional insight into this hypothetical model. The understanding of neuroendocrine modulation of food reward, as well as food reward modulation by diet and obesity, may point to new directions for therapeutic approaches to overeating or eating disorders

Leptin reverses sucrose-conditioned place preference in food-restricted rats

Previous studies have suggested that food restriction can modify performance in the conditioned place preference (CPP) paradigm. In the present study, we tested the hypotheses that food restriction would enhance the development of a CPP to low-calorie sucrose pellets and that peripheral leptin replacement in food-restricted animals would reverse this effect. Using a range of 45-mg sucrose pellets (0-15 pellets) as a reward, we observed that a significant place preference was conditioned in food-restricted, but not ad libitum-fed rats. This CPP was reversed either by treatment of food-restricted rats with the dopamine receptor antagonist alpha-flupenthixol (200 microg/kg ip) during the training protocol or by chronic subcutaneous replacement of leptin (125 microg/kg/day) that attenuated the food restriction-induced decrease of circulating leptin. We conclude that dopaminergic signaling and the fall of plasma leptin concentrations contribute to the CPP of food-restricted rats. This finding suggests that in addition to metabolic adaptations, hypoleptinemia results in behavioral adaptations during states of energy deprivation

The action of leptin in the ventral tegmental area to decrease food intake is dependent on Jak-2 signaling

Recent evidence suggests that leptin reduces food intake via actions in the brain circuitry of food reward, such as the ventral tegmental area (VTA), as leptin receptors are present in the VTA, and leptin injection in the VTA reduces food intake. In the hypothalamus, leptin-induced anorexia requires signaling via Janus kinase-signal transducer and activator of transcription (Jak-STAT), insulin receptor substrate (IRS)-phosphatidylinositol 3-kinase (PI 3-kinase), and mammalian target of rapamycin (mTOR). In this study, we determined whether leptin activates each of these signal transduction pathways in the VTA and whether these signaling pathways are required for VTA-leptin induced anorexia. Here, we show that pSTAT3-Tyr705, a marker of leptin activation, was induced in a midbrain region containing the VTA and substantia nigra following either intracerebroventricular leptin or direct administration of leptin to the VTA, but these interventions failed to increase levels of either pAKT-Ser473 or phospho-p70S6K-Thr389, markers of IRS-PI 3-kinase and mTOR signaling, respectively. Moreover, the effect of intra-VTA leptin administration to reduce 4- and 20-h food intake and 20-h body weight was blocked by an inhibitor of Jak-2, at a dose that had no effect on food intake or body weight by itself, but not by local inhibition of either PI 3-kinase (LY-294002) or mTOR (rapamycin) in this timeframe. Taken together, these data support the hypothesis that leptin signaling in the VTA is involved in the regulation of energy balance, but, in contrast to the leptin signaling in the hypothalamus, these effects are mediated predominantly via Jak-2 signaling rather than via the IRS-PI 3-kinase or mTOR signaling pathway

Antecedent Hindbrain Glucoprivation Does Not Impair the Counterregulatory Response to Hypoglycemia

Recurrent hypoglycemia impairs hormonal counterregulatory responses (CRRs) to further bouts of hypoglycemia. The hypothalamus and hindbrain are both critical for sensing hypoglycemia and triggering CRRs. Hypothalamic glucose sensing sites are implicated in the pathogenesis of defective CRRs; however, the contribution of hindbrain glucose sensing has not been elucidated. Using a rat model, we compared the effect of antecedent glucoprivation targeting hindbrain or hypothalamic glucose sensing sites with the effect of antecedent recurrent hypoglycemia on CRR to hypoglycemia induced 24 h later. Recurrent hypoglycemia decreased sympathoadrenal (1,470 ± 325 vs. 3,811 ± 540 pg/ml in controls [t = 60 min], P = 0.001) and glucagon secretion (222 ± 43 vs. 494 ± 56 pg/ml in controls [t = 60]), P = 0.003) in response to hypoglycemia. Antecedent 5-thio-glucose (5TG) injected into the hindbrain did not impair sympathoadrenal (3,806 ± 344 pg/ml [t = 60]) or glucagon (513 ± 56 pg/ml [t = 60]) responses to subsequent hypoglycemia. However, antecedent 5TG delivered into the third ventricle was sufficient to blunt CRRs to hypoglycemia. These results show that hindbrain glucose sensing is not involved in the development of defective CRRs. However, neural substrates surrounding the third ventricle are particularly sensitive to glucoprivic stimulation and may contribute importantly to the development of defective CRRs.There is a long history of anatomical and pharmacological evidence supporting the role of both the hypothalamus (6–14) and hindbrain (15–18) in glucose sensing and in the initiation of hormonal CRRs. Although there is evidence supporting the role of the hypothalamus, in particular the ventromedial nucleus, in the development of defective hypoglycemic CRRs (10,19–21), the contribution of hindbrain glucose sensing mechanisms is unknown. Given their anatomical differences and the fact that hindbrain glucoreceptors can function independently from the hypothalamus (16), recurrent hypoglycemic stimulation may differentially affect these two distinct glucose sensing brain regions. In the present study, we adapted our recurrent hypoglycemia rat model, which results in significant deficits in hormonal CRRs (22), to identify the contribution of a hindbrain glucose sensing site (17) in defective CRRs. We compared the effect of antecedent 5-thio-glucose (5TG), delivered into the hindbrain or third ventricle, with the effect of antecedent recurrent hypoglycemia on hormonal CRRs to subsequent hypoglycemia. We hypothesized that either antecedent hindbrain or third ventricular glucoprivation would impair CRRs to subsequent hypoglycemia. As expected, antecedent third ventricular glucoprivation, similar to recurrent hypoglycemia, blunted hormonal CRRs to subsequent hypoglycemia. In marked contrast, antecedent glucoprivation localized to a caudal hindbrain glucose sensing site did not impair hypoglycemia CRRs. Therefore, the hindbrain does not appear to be vulnerable to the central nervous system's adaptive mechanisms that impair CRRs under conditions of recurren

Acute THPVP inactivation decreases the glucagon and sympathoadrenal responses to recurrent hypoglycemia

The posterior paraventricular nucleus of the thalamus (THPVP) has been identified as a forebrain region that modulates the central nervous system (CNS) response to recurrent experiences of stressors. The THPVP is activated in response to a single (SH) or recurrent (RH) experience of the metabolic stress of hypoglycemia. In this study, we evaluated whether temporary experimental inactivation of the THPVP would modify the neuroendocrine response to SH or RH. Infusion of lidocaine (LIDO) or vehicle had no effect on the neuroendocrine response to SH, comparable to findings with other stressors. THPVP vehicle infusion concomitant with RH resulted in a prevention of the expected impairment of neuroendocrine responses, relative to SH. LIDO infusion with RH resulted in significantly decreased glucagon and sympathoadrenal responses, relative to SH. These results suggest that the THPVP may contribute to the sympathoadrenal stimulation induced by hypoglycemia; and emphasizes that the THPVP is a forebrain region that may contribute to the coordinated CNS response to metabolic stressors