Role of dorsal and ventrolateral portions of the periaqueductal gray in the modulation of defensive behaviors and antinociception induced by aversive situations in mice

Threatening situations (e.g., exposure to an elevated plus-maze with four open arms oEPM) induce behavioral and neurovegetative responses generally accompanied by antinociception and activation of the hypothalamus-pituitary-adrenal (HPA) axis. Furthermore, it is known that the midbrain periaqueductal gray (PAG) is part of the neural substrate for the expression of behaviorally and neurovegetative alterations in response to aversive stimuli. In addition, the PAG is longitudinally divided into four columns (dorsomedial, dorsolateral, lateral and ventrolateral) that are involved in coordinating distinct strategies for animals coping with different types of stress, threat and pain. The present study analyzed the plasmatic levels of corticosterone when mice with or without prior 2.5% formalin injection into the right hind paw (nociception test) were exposed in one of the 3 types of EPM, the enclosed (eEPM: 4 enclosed arms - non-aversive situation), the standard (sEPM: two open and two closed arms - aversive situation with the possibility of avoidance/flight) or the open (oEPM: 4 open arms - aversive situation without the possibility of avoidance/flight) EPM. The study also investigated the temporal evaluation of the oEPM-induced antinociception when mice were kepted in (for 30 min) or removed from (after 10 min of exposure) that aversive environment (i.e., the oEPM). The characterization of the PAG participation in this type of antinociception was evaluated by irreversible (produced by NMDA injection) uni or bilateral lesion of dorsal PAG portion (dPAG: dorsolateral and dorsomedial columns) and bilateral ventrolateral PAG lesion (vlPAG). Finally, the effects of dPAG or vlPAG lesion on the anxiety indices were investigated in mice with or without prior formalin injection during the exposure to the sEPM. Results showed that the eEPM exposure increased the plasmatic concentration of corticosterone (CORT), however sEPM or oEPM exposure animals showed higher levels of CORT than eEPM-exposed mice. Moreover, when animals were submitted to the formalin test high, but similar levels of this glucocorticoid were verified after the exposure to the different EPM, suggesting that nociception also has provoked a ceiling effect on plasma corticosterone concentration. Results also showed that the oEPM-induced antinociception ceased immediately after mice withdrawal from the aversive situation. However, this pain inhibition response remained unchanged for approximately 20 min in animals that were kept in the threatening condition. Finally, the lesions of different portions of PAG showed that neither dPAG nor vlPAG appear to be involved in the modulation of the oEPM-induced antinociception. Curiously, vlPAG lesion reduced the nociceptive response in animals submitted to the eEPM and increased the locomotion during eEPM and oEPM exposure. Moreover, bilateral dPAG lesion reduced anxiety indices (% of open arm entries and % of open arm time) only in mice that had not received prior injection of formalin, suggesting that nociception impaired the anxiolytic-like effect produced by dPAG lesion. It is important to highlight that vlPAG lesion did not alter the anxiety-like indices and the locomotion in mice not submitted to the concurrent nociceptive stimulation. (AU)