Obesity is caused by excess calories gained over calories expended, allowing energy to accumulate in fat cells as lipids. One method of reducing obesity is to control appetite so that the body consumes more than it gains. This study aimed to investigate the effects of a high-fat diet and genetic changes on appetite in mice. MicroRNA (miRNA) is a 22-nucleotide-long RNA molecule that has been shown to influence gene expression by binding to target genes.miR-137 in this study has a high level of expression in the brain. Previously, after being fed by HFD, mice with heterozygous (miR-137+/-) gained more body weight and ate more food than the control group (miR-137+/+), indicating that miR-137 is related to appetite. Due to the early death of knockout mice, miR-137+/- mice were primarily utilized in the experiment. According to the experimental design, adult mice were fed regular diet until they were six weeks old before being given HFD for three days. Heterozygous mice gained more weight and ate more food than the control group (miR-137+/+). They also had higher appetite-stimulating gene neuropeptide Y (NPY) levels. The association between miR-137 and appetite has been tentatively confirmed. On the other hand, we attempted to investigate the impact of high-fat diet on appetite. First, wild-type mice were divided into two groups and fed RD and HFD for six weeks. The group which ate HFD gained more weight and consumed less food, but there was no significant change in appetite-related genes. We hypothesized that a small amount of HFD could meet the daily energy demand of WT mice, so food intake was reduced, and thus the follow-up experiment time was reduced to three days. WT mice were then divided into four groups as follows: the first group was fed RD for three days, the second group was fed HFD for three days, the third group was fed HFD for 14 days, and the fourth group was fed HFD for three days followed by RD for three days. The mice's food consumption was recorded before and after the experiment. It was discovered that the food intake of mice increased significantly on the day of the HFD change and then decreased to the initial level or lowered the following day. Following the experiment, RNA was extracted from the hypothalamus, hippocampus, and amygdala for RNA sequencing. Using Ingenuity Pathway Analysis and Gene Set Enrichment Analysis, it was discovered that RAR Related Orphan Receptor A (RORA) in the Th17 activation pathway might be the target gene of miR-137. It may also indirectly activate the appetite suppressor gene Pro-opiomelanocortin (POMC) via Interleukin 1 beta (IL1B). Finally, we found an increase in Th17 cells in the brain's hypothalamus of mice consuming long-term HFD using immunofluorescence staining. These findings demonstrated that decreasing miR-137 in vivo affected mice's appetite for high-fat foods. On the other hand, high-fat diet may regulate appetite-related neurons in the hypothalamus via an immune-related pathway, which needs to be confirmed in future research.