Basal activation of astrocytic Nrf2 in neuronal culture media: challenges and implications for neuron-astrocyte modelling

Mohamed M O Elsharkasi, Beatrice Villani, Geoffrey Wells, Fiona Kerr
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Abstract

As a gate-keeper of anti-oxidant, anti-inflammatory and xenobiotic cell protection mechanisms, the transcription factor Nrf2 has been implicated as a promising therapeutic target for several neurodegenerative diseases, leading to the development of Nrf2 activators targeting Keap1-dependent and independent regulatory mechanisms. This study aimed to evaluate the efficacy of a Keap1-Nrf2 protein-protein interaction disruptor, 18e, in comparison with classical electrophilic Nrf2 activators, CDDO-Me and Dimethylfumarate (DMF), with a view to measuring their effects on neuronal protection using LUHMES neuron-astrocyte co-cultures. Astrocytes play a crucial role in regulating neuronal physiology in health and disease, including Nrf2 neuroprotective responses. As neurons require specific conditions for their differentiation and maintenance, most 2D and 3D co-culture systems use medias containing high glucose and a variety of growth factors, allowing astrocytes to survive without the media negatively impacting neuronal function. Few studies, however, assess the molecular adaptations of astrocytes in response to changes from astrocyte maintenance medias alone, and the potential consequences for neuronal function, which may represent technical rather than physiological changes. Our findings show that while Nrf2 can be effectively activated by 18e, DMF and CDDO-Me in human primary cortical astrocyte monocultures, their efficacy is lost in the LUHMES-astrocyte co-culture, as measured by NQO1 enzymatic activity. Further investigation revealed that the Advanced DMEM/F12-based LUHMES differentiation media maximally induced basal Nrf2 activity in astrocytes alone, in comparison to complete astrocyte maintenance media. Analysis of media components revealed that this was not due tetracycline or high glucose, and was unlikely to be due to REDOX-inducing phenol-red, the concentration of which is comparable across all medias used in our study. Although Neurobasal slightly activated basal Nrf2 compared to astrocyte media, trends toward further activation were observed in the presence of 18e and DMF, suggesting that this media impacts astrocytic Nrf2 responses less than Advanced DMEM/F12. Numerous studies model oxidative stress and neuroinflammation, key features of neurological diseases, using neuronal systems. As Nrf2 is a key regulator of cellular damage, the effects of these stressors could be confounded by cellular environments that maximally activate basal Nrf2, as observed in our experiments. Hence, this study highlights the need for caution in media selection for neuron-astrocyte co-culture modelling, not only for researchers investigating Nrf2 therapeutics, but also for other mechanisms by which astrocytes influence neuronal function in health and disease.
神经元培养基中星形胶质细胞 Nrf2 的基础激活:神经元-星形胶质细胞模型的挑战和意义
作为抗氧化、抗炎和异种生物细胞保护机制的守门员,转录因子 Nrf2 已被认为是治疗多种神经退行性疾病的有希望的靶点,从而导致了针对 Keap1 依赖性和独立调控机制的 Nrf2 激活剂的开发。本研究旨在评估Keap1-Nrf2蛋白-蛋白相互作用干扰物18e与经典亲电性Nrf2激活剂CDDO-Me和富马酸二甲酯(DMF)相比的疗效,以便利用LUHMES神经元-星形胶质细胞共培养物测量它们对神经元保护的作用。星形胶质细胞在调节神经元的健康和疾病生理功能(包括 Nrf2 神经保护反应)方面起着至关重要的作用。由于神经元的分化和维持需要特定的条件,大多数二维和三维共培养系统都使用含有高葡萄糖和多种生长因子的培养基,这样星形胶质细胞就能存活下来,而不会对神经元的功能产生负面影响。然而,很少有研究评估星形胶质细胞对单纯星形胶质细胞维持介质变化的分子适应性,以及对神经元功能的潜在后果,这可能代表技术性而非生理性变化。我们的研究结果表明,在人类原代皮质星形胶质细胞单培养基中,18e、DMF 和 CDDO-Me 能有效激活 Nrf2,但在 LUHMES-星形胶质细胞共培养中,根据 NQO1 酶活性测定,它们的功效消失了。进一步研究发现,与完整的星形胶质细胞维持培养基相比,基于高级DMEM/F12的LUHMES分化培养基能最大限度地诱导星形胶质细胞的Nrf2基础活性。对培养基成分的分析表明,这不是四环素或高葡萄糖造成的,也不太可能是诱导 REDOX 的酚红造成的,因为我们研究中使用的所有培养基中酚红的浓度都相当。虽然与星形胶质细胞培养基相比,Neurobasal 稍微激活了基础 Nrf2,但在 18e 和 DMF 存在的情况下,观察到了进一步激活的趋势,这表明这种培养基对星形胶质细胞 Nrf2 反应的影响小于高级 DMEM/F12。许多研究利用神经元系统对氧化应激和神经炎症(神经系统疾病的主要特征)进行建模。由于 Nrf2 是细胞损伤的关键调节因子,这些应激源的影响可能会被最大程度激活基础 Nrf2 的细胞环境所混淆,正如我们在实验中观察到的那样。因此,这项研究强调了神经元-星形胶质细胞共培养模型的培养基选择需要谨慎,这不仅适用于研究 Nrf2 疗法的研究人员,也适用于星形胶质细胞在健康和疾病中影响神经元功能的其他机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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