Department of Anatomy and Neurobiology, Virginia Commonwealth University, Richmond, VA 23298, USA.
Brain. 2011 Dec;134(Pt 12):3616-31. doi: 10.1093/brain/awr281. Epub 2011 Nov 18.
Individuals infected with human immunodeficiency virus-1 who abuse opiates can have a higher incidence of virus-associated neuropathology. Human immunodeficiency virus does not infect neurons, but viral proteins such as transactivator of transcription and glycoprotein 120, originating from infected glia, are neurotoxic. Moreover, functional changes in glial cells that enhance inflammation and reduce trophic support are increasingly implicated in human immunodeficiency virus neuropathology. In previous studies, co-exposure with morphine enhanced transactivator of transcription neurotoxicity towards cultured striatal neurons. Since those cultures contained µ-opioid receptor-expressing astroglia and microglia, and since glia are the principal site of infection in the central nervous system, we hypothesized that morphine synergy might be glially mediated. A 60 hour, repeated measures paradigm and multiple co-culture models were used to investigate the cellular basis for opiate-enhanced human immunodeficiency virus neurotoxicity. Morphine co-exposure significantly enhanced transactivator of transcription-induced neuron death when glia were present. Synergistic effects of morphine on transactivator of transcription neurotoxicity were greatest with neuron-glia contact, but also occurred to a lesser extent with glial conditioned medium. Importantly, synergy was lost if glia, but not neurons, lacked µ-opioid receptors, indicating that opiate interactions with human immunodeficiency virus converge at the level of µ-opioid receptor-expressing glia. Morphine enhanced transactivator of transcription-induced inflammatory effectors released by glia, elevating reactive oxygen species, increasing 3-nitrotyrosine production by microglia, and reducing the ability of glia to buffer glutamate. But neuron survival was reduced even more with glial contact than with exposure to conditioned medium, suggesting that noxious elements associated with cell contact augment the toxicity due to soluble factors. Similar morphine-transactivator of transcription synergy was also observed in studies with the clade C sequence of HIV-1 transactivator of transcription, which did not cause neuron death unless morphine was present. Several paradoxical observations related to opiate effects were noted when µ-opioid receptors were specifically ablated from either glia or neurons. This suggests that µ-opioid receptor loss in isolated cell types can fundamentally distort cell-to-cell signalling, revealing opponent processes that may exist in individual cell types. Our findings show the critical role of glia in orchestrating neurotoxic interactions of morphine and transactivator of transcription, and support the emerging concept that combined exposure to opiates and human immunodeficiency virus drives enhanced pathology within the central nervous system.
感染人类免疫缺陷病毒-1 的滥用阿片类药物的个体可能更容易发生与病毒相关的神经病理学变化。人类免疫缺陷病毒并不感染神经元,但源自受感染的神经胶质细胞的病毒蛋白,如转录激活因子和糖蛋白 120,具有神经毒性。此外,增强炎症和减少营养支持的神经胶质细胞的功能变化,越来越多地与人类免疫缺陷病毒的神经病理学有关。在以前的研究中,与吗啡共同暴露会增强培养的纹状体神经元中转录激活因子的神经毒性。由于这些培养物中含有 µ 阿片受体表达的星形胶质细胞和小胶质细胞,并且由于胶质细胞是中枢神经系统感染的主要部位,因此我们假设吗啡协同作用可能是由胶质细胞介导的。使用 60 小时重复测量范式和多种共培养模型来研究阿片类药物增强的人类免疫缺陷病毒神经毒性的细胞基础。当存在胶质细胞时,吗啡共同暴露会显著增强转录激活因子诱导的神经元死亡。吗啡对转录激活因子神经毒性的协同作用在神经元-胶质细胞接触时最大,但在胶质细胞条件培养基中也会以较小的程度发生。重要的是,如果没有 µ 阿片受体,胶质细胞而不是神经元缺失,则协同作用丧失,表明阿片类药物与人类免疫缺陷病毒的相互作用在 µ 阿片受体表达的胶质细胞水平上收敛。吗啡增强了由胶质细胞释放的转录激活因子诱导的炎症效应物,增加了活性氧,增加了小胶质细胞中 3-硝基酪氨酸的产生,并降低了胶质细胞缓冲谷氨酸的能力。但是,与暴露于条件培养基相比,与胶质细胞接触会导致神经元存活减少更多,这表明与细胞接触相关的有害因素会增强由于可溶性因子引起的毒性。在使用人类免疫缺陷病毒-1 转录激活因子的 clade C 序列的研究中也观察到类似的吗啡-转录激活因子协同作用,除非存在吗啡,否则该序列不会导致神经元死亡。当 µ 阿片受体从胶质细胞或神经元中特异性缺失时,观察到几个与阿片类药物作用有关的悖论。这表明,在单个细胞类型中,µ 阿片受体的缺失可能会从根本上扭曲细胞间信号传递,揭示了可能存在于单个细胞类型中的对立过程。我们的研究结果表明胶质细胞在协调吗啡和转录激活因子的神经毒性相互作用中起着关键作用,并支持这样一种新兴概念,即联合暴露于阿片类药物和人类免疫缺陷病毒会导致中枢神经系统内增强的病理学变化。