Substance P has been known to be antinociceptive when given at the supraspinal level and is involved in stress-induced analgesia (SIA), primarily through the neurokinin-1 receptor (NK1R). However, its action mechanism(s) remain unclear while may involve endocannabinoids. Previously, we have found that activation of orexin 1 receptors in the ventrolateral periaqueductal gray (vlPAG) can induce antinociception through the endocannabinoid retrograde signaling, and this effect may contribute to SIA induced by orexin A. Besides, an electrophysiological study showed that substance P can activate glutamatergic neurons in the PAG to release massive glutamate that activates perisynaptic type 5 metabotropic glutamate receptor (mGluR5), yielding endocannabinoid that engages on the cannabinoid 1 receptor (CB1R) of presynaptic GABAergic terminals to inhibit GABA release, producing retrograde disinhibition in the PAG. We, therefore, validated a hypothesis in this study that orexin A activates neurokinin-containing neurons in the vlPAG to release substance P and induce antinociception through the glutamate-mGluR5-endocannabinoid-CB1R signaling, and this mechanism may contribute to orexin A-induced SIA using the pharmacological approach. The SIA model was induced by giving mice a 30-min restraint stress and the antinociceptive response was accessed by the withdrawal latency of mice in the hot-plate test in mice. All drugs were administered by intra-vlPAG (i.pag.) microinjection. Besides, the level of substance P in the homogenate of the vlPAG in restrained un-restrained mice was also measured by enzyme immunoassay (EIA). First, we found that i.pag. microinjection of substance P significantly increased the withdrawal latency. This analgesic effect was blocked by MPEP, an mGluR5 antagonist and AM251, a CB1R antagonist, suggesting CB1Rs and mGluR5s are involved in the analgesic effect of substance P. Second, i.pag. orexin A produced a significant antinociceptive effect, in a manner blocked by i.pag. L-703,606, an NK1 receptor antagonist, and MPEP. This suggests that NK1R and mGluR5 are involved in the analgesic effect of orexin A. Third, we have established a SIA model induced by acute restraint stress in mice, i.e. the withdrawal latency of the mouse restrained in a 50-ml centrifuge tube was significantly longer than in the unrestrained group. This SIA was significantly prevented by i.pag. pretreatment with either L-703,606 or MPEP at the dose that did not affect the locomotor activity. Fourth, the substance P protein level in the vlPAG homogenate was significantly higher in restrained mice, as compared to the unrestrained control group. Fifth, stress-induced elevation of substance P in the vlPAG was significantly reversed by i.pag. pretreatment of SB-334867, a selective orexin OX1 receptor antagonist. The results in this study and previous electrophysiological results suggest that substance P produces supraspinal analgesia through activating glutamatergic neurons in the vlPAG to release glutamate that activates mGluR5, resulting in endocannabinoid retrograde disinhibition in the vlPAG. Since SIA can be blocked by NK1R, mGluR5 and OX1R antagonists, it is suggested that SIA is mediated orexins that are released during restraint stress to induce analgesia via releasing substance P that produces disinhibition in the vlPAG via the mGluR5-endocannabinoid mechanism.