Neuropsychology Doctoral Sub-Program, Queens College, City University of New York, Flushing, NY 11367, USA.
Brain Res. 2012 Mar 14;1443:34-51. doi: 10.1016/j.brainres.2012.01.015. Epub 2012 Jan 17.
Food intake is significantly increased following administration of agonists of GABA and opioid receptors into the nucleus accumbens shell (NACs) and ventral tegmental area (VTA). GABA-A or GABA-B receptor antagonist pretreatment within the VTA or NACs differentially affects mu-opioid agonist-induced feeding elicited from the same site. Correspondingly, general or selective opioid receptor antagonist pretreatment within the VTA or NACs differentially affects GABA agonist-induced feeding elicited from the same site. Regional interactions have been evaluated in feeding studies by administering antagonists in one site prior to agonist administration in a second site. Thus, opioid antagonist-opioid agonist and GABA antagonist-GABA agonist feeding interactions have been identified between the VTA and NACs. However, pretreatment with GABA-A or GABA-B receptor antagonists in the VTA failed to affect mu opioid agonist-induced feeding elicited from the NACs, and correspondingly, these antagonists administered in the NACs failed to affect mu opioid-induced feeding elicited from the VTA. To evaluate whether regional and reciprocal VTA and NACs feeding interactions occur for opioid receptor modulation of GABA agonist-mediated feeding, the present study examined whether feeding elicited by the GABA-B agonist, baclofen microinjected into the NACs was dose-dependently blocked by pretreatment with general (naltrexone: NTX), mu (beta-funaltrexamine: BFNA), kappa (nor-binaltorphamine: NBNI) or delta (naltrindole: NTI) opioid antagonists in the VTA, and correspondingly, whether VTA baclofen-induced feeding was dose-dependently blocked by NACs pretreatment with NTX, BFNA, NBNI or NTI in rats. Bilateral pairs of cannulae aimed at the VTA and NACs were stereotaxically implanted in rats, and their food intakes were assessed following vehicle and baclofen (200 ng) in each site. Baclofen produced similar magnitudes of increased food intake following VTA and NACs treatment. Baclofen administration in the VTA or NACs was also preceded by administration of NTX (0.1, 1, 5 μg, 0.5 h), BFNA (0.4, 4 μg, 24 h), NBNI (0.6, 6 μg, 0.5 h) or NTI (0.4, 4 μg, 0.5 h) into the other site with intake measured 1, 2 and 4 h after agonist treatment. VTA NTX significantly reduced NACs baclofen-induced feeding. Correspondingly, NACs NTX significantly reduced VTA baclofen-induced feeding, indicating a robust and bidirectional general opioid and GABA-B receptor feeding interaction. Whereas the high, but not low VTA BFNA dose reduced NACs baclofen-induced feeding, NACs BFNA failed to affect VTA baclofen-induced feeding, indicating a unidirectional mu opioid and GABA-B receptor feeding interaction. Whereas VTA NBNI at both doses reduced NACs baclofen-induced feeding, the high, but not low NACs NBNI dose significantly reduced VTA baclofen-induced feeding, indicating a bidirectional kappa opioid and GABA-B receptor feeding interaction. Whereas VTA NTI only transiently reduced NACs baclofen-induced feeding, NACs NTI failed to affect VTA baclofen-induced feeding, indicating a weak unidirectional delta opioid and GABA-B receptor interaction. Whereas administration of NTX or BFNA into the NACs or VTA marginally reduced spontaneous food intake, NBNI or NTI into the same sites failed to alter food intake alone. Therefore, the present study suggests that GABA employs a distributed brain network in mediating its ingestive effects that is dependent upon intact opioid receptor signaling with kappa opioid receptors more involved than mu and delta opioid receptors underlying these regional effects. An alternative hypothesis to be considered is that these effects could be the sum of two independent drug effects (opioid antagonists decreasing and baclofen increasing food intake).
进食量显著增加后,管理的激动剂 GABA 和阿片受体进入伏隔核壳 (NACs) 和腹侧被盖区 (VTA)。GABA-A 或 GABA-B 受体拮抗剂预处理 VTA 或 NACs 不同程度地影响了从同一部位引出的 μ-阿片激动剂诱导的进食。相应地,在 VTA 或 NACs 中给予一般或选择性阿片受体拮抗剂预处理也会影响从同一部位引出的 GABA 激动剂诱导的进食。在进食研究中通过在第二部位给予激动剂之前在第一部位给予拮抗剂来评估区域相互作用。因此,已经在 VTA 和 NACs 之间鉴定了阿片拮抗剂-阿片激动剂和 GABA 拮抗剂-GABA 激动剂的进食相互作用。然而,在 VTA 中给予 GABA-A 或 GABA-B 受体拮抗剂预处理未能影响从 NACs 引出的 μ 阿片激动剂诱导的进食,相应地,这些拮抗剂在 NACs 中给予未能影响从 VTA 引出的 μ 阿片诱导的进食。为了评估 VTA 和 NACs 之间是否存在阿片受体调制 GABA 激动剂介导的进食的区域和相互作用,本研究检查了 GABA-B 激动剂 baclofen 微注射到 NACs 中是否剂量依赖性地被 VTA 中的一般 (纳曲酮:NTX)、μ (β-芬太尼:BFNA)、κ (去甲纳曲酮:NBNI)或 δ (纳曲吲哚:NTI)阿片受体拮抗剂预处理阻断,相应地,VTA 中的 baclofen 诱导的进食是否剂量依赖性地被 NACs 中的 NTX、BFNA、NBNI 或 NTI 预处理阻断在大鼠中。在大鼠中立体定向植入双侧对向 VTA 和 NACs 的套管,并在每个部位给予载体和 baclofen(200ng)后评估其食物摄入量。Baclofen 产生类似幅度的增加的食物摄入量后,VTA 和 NACs 治疗。Baclofen 给药前还在 VTA 或 NACs 中给予 NTX(0.1、1、5μg,0.5h)、BFNA(0.4、4μg,24h)、NBNI(0.6、6μg,0.5h)或 NTI(0.4、4μg,0.5h),并在激动剂处理后 1、2 和 4 小时测量摄入。VTA NTX 显著减少了 NACs 中 baclofen 诱导的进食。相应地,NACs NTX 显著减少了 VTA baclofen 诱导的进食,表明存在强大和双向的一般阿片受体和 GABA-B 受体的进食相互作用。虽然高剂量但不是低剂量的 VTA BFNA 减少了 NACs 中 baclofen 诱导的进食,但 NACs BFNA 未能影响 VTA baclofen 诱导的进食,表明存在单向 μ 阿片受体和 GABA-B 受体的进食相互作用。虽然 VTA NBNI 两种剂量均减少了 NACs 中 baclofen 诱导的进食,但高剂量但不是低剂量的 NACs NBNI 显著减少了 VTA baclofen 诱导的进食,表明存在双向 κ 阿片受体和 GABA-B 受体的进食相互作用。虽然 VTA NTI 仅短暂地减少了 NACs 中 baclofen 诱导的进食,但 NACs NTI 未能影响 VTA baclofen 诱导的进食,表明存在弱的单向 δ 阿片受体和 GABA-B 受体相互作用。虽然 NTX 或 BFNA 给予 NACs 或 VTA 轻微减少了自发进食量,但 NBNI 或 NTI 给予相同部位未能单独改变进食量。因此,本研究表明 GABA 采用分布式大脑网络来介导其摄取效应,该网络依赖于完整的阿片受体信号,其中 κ 阿片受体比 μ 和 δ 阿片受体更参与这些区域效应。需要考虑的另一个假设是,这些效应可能是两种独立药物效应的总和(阿片受体拮抗剂减少和 baclofen 增加食物摄入量)。
