Accumulating evidences have revealed modulatory roles of immune activities on normal physiology of central nervous system. Also, inflammation in the periphery is associated with neurological diseases through the functions of cytokines. The studies of cytokine actions on neurons were mainly focused on single specific cytokines, such as TNF-α, IL-6, etc, the influence of inflammatory environment, which contained mixtures of numerous cytokines, chemokines, and pro-inflammatory molecules secreted by innate immune cells, are not fully understood. POMC/CART neurons in the arcuate nucleus of the hypothalamus play crucial roles of regulating appetite, energy expenditure, and central control of metabolism. Chronic inflammation in the hypothalamus induced food intake dysregulation and abnormal metabolism. This study aimed to investigate of neural alterations induced by the inflammatory milieu. We conducted cellular studies by culturing hypothalamic POMC neurons with conditioned medium from LPS stimulated bone marrow derived macrophages, whereas high fat diet-fed mice were chosen for examining physiological impacts. We first examine the leptin and insulin signaling in mHypo-POMC/GFP cells. Short-term stimulation of leptin or insulin activates the PI3K-AKT-mTOR pathway downregulating AMPK and increases the expression of POMC gene, while long-term incubation upregulates the expression of negative-regulatory gene SOCS3 and autophagy gene ATG7 to maintain body homeostasis. The leptin and insulin signaling in POMC neurons were altered under inflammatory conditions. POMC gene expression is inhibited after long-term incubation with pro-inflammation cytokines. Also, and the activation of AKT and mTOR is relatively weakened after leptin and insulin stimulation. Furthermore, the metabolism-related cellular responses, such as mitochondrial functions and dynamics in POMC neurons, against proinflammatory stimuli, will be elucidated. Although intracellular ROS/RNS levels were elevated, the results of expressions of the electron transport chain genes and proton leakage suggested that mitochondria in POMC neurons remained undamaged. In addition, respiratory rate and overall mitochondrial function revealed a trend of decrease in the inflammatory environment. Inflammatory milieu induced significant decrease of mitochondrial uncoupling and slowed down mitochondrial dynamics by downregulating the expression of both fission and fusion genes. The balance of mitochondrial fission and fusion was also changed resulting in the enlargement of overall mitochondrial size. In summary, the mitochondrial alterations induced by inflammatory environment suggested mitochondrial functions and metabolic regulation abilities are disrupted in hypothalamic POMC neurons. Finally, we examined the metabolic regulations, inflammation status, arcuate functions and mitochondrial status in the high-fat diet-fed mice. Our data revealed that after feeding high-fat diet fed to C57BL/6 mice for four weeks, the testing developed obesity and systemic inflammation, but not metabolic dysregulation such as elevated blood triglycerides. The expression of metabolic regulating genes of arcuate POMC neurons indicated that the energy balance machinery in the arcuate nucleus remained functioning after 4-weeks of high fed diet feeding. Mitochondrial dynamics was promoted in the hypothalamus, suggesting the mitochondrial regulation in the calorie excessive conditions was not disrupted. These regulations could be altered in longer feeding of high fat diet for the development of further metabolic dysregulation, such as misbalance of glucose or lipid metabolic homeostasis. In conclusion, our results displayed the effects of inflammation milieu on metabolic regulation and mitochondrial functions in hypothalamic POMC neurons, but the physiological significance of these alterations needs further investigation.