International Centre for Neurotherapeutics, Dublin City University, Glasnevin, Dublin, Ireland,
International Centre for Neurotherapeutics, Dublin City University, Glasnevin, Dublin, Ireland.
Cell Physiol Biochem. 2021 Jul 10;55(4):428-448. doi: 10.33594/000000394.
BACKGROUND/AIMS: Nociceptors detect noxious capsaicin (CAPS) via the transient receptor potential vanilloid 1 (TRPV1) ion channel, but coding mechanisms for relaying CAPS concentration [CAPS] remain obscure. Prolonged (up to 1h.) exposure to CAPS is used clinically to desensitise sensory fibres for treatment of neuropathic pain, but its signalling has typically been studied in cultures of dissociated sensory neurons employing low cell numbers and very short exposure times. Thus, it was pertinent to examine responses to longer CAPS exposures in large populations of adult neurons.
Confocal fluorescence microscopy was used to monitor the simultaneous excitation by CAPS of neuronal populations in intact L3/4 dorsal root ganglia (DRG) explants from adult pirt-GCaMP3 mice that express a cytoplasmic, genetically-encoded Ca sensor in almost all primary sensory neurons. Peak analysis was performed using GraphPad Prism 9 to deconstruct the heterogenous and complex fluorescence signals observed into informative, readily-comparable measurements: number of signals, their lag time, maximum intensity relative to baseline (Max.) and duration.
Exposure for 5 min. to CAPS activated plasmalemmal TRPV1 and led to increased fluorescence due to Ca entry into DRG neurons (DRGNs), as it was prevented by capsazepine or removal of extracellular Ca. Increasing [CAPS] (0.3, 1 and 10 μM, respectively) evoked signals from more neurons (123, 275 and 390 from 5 DRG) with shorter average lag (6.4 ± 0.4, 3.3 ± 0.2 and 1.9 ± 0.1 min.) and longer duration (1.4 ± 0.2, 2.9 ± 0.2 and 4.8 ± 0.3 min.). Whilst raising [CAPS] produced a modest augmentation of Max. for individual neurons, those with large increases were selectively expedited; this contributed to a faster onset and higher peak of cumulative fluorescence for an enlarged responding neuronal population. CAPS caused many cells to fluctuate between high and low levels of fluorescence, with consecutive pulses increasing Max. and duration especially when exposure was extended from 5 to 20 min. Such signal facilitation counteracted tachyphylaxis, observed upon repeated exposure to 1 μM CAPS, preserving the cumulative fluorescence over time (signal density) in the population.
Individual neurons within DRG differed extensively in the dynamics of response to CAPS, but systematic changes elicited by elevating [CAPS] increased signal density in a graded manner, unveiling a possible mechanism for population coding of responses to noxious chemicals. Signal density is sustained during prolonged and repeated exposure to CAPS, despite profound tachyphylaxis in some neurons, by signal facilitation in others. This may explain the burning sensation that persists for several hours when CAPS is used clinically.
背景/目的:伤害感受器通过瞬时受体电位香草酸 1(TRPV1)离子通道检测有害的辣椒素(CAPS),但传递 CAPS 浓度[CAPS]的编码机制仍不清楚。长时间(长达 1 小时)暴露于 CAPS 临床上用于使感觉纤维脱敏,以治疗神经性疼痛,但它的信号转导通常在使用低细胞数和极短暴露时间的分离感觉神经元培养物中进行研究。因此,有必要在大量成年神经元中研究更长时间的 CAPS 暴露后的反应。
共聚焦荧光显微镜用于监测成年 pirt-GCaMP3 小鼠完整 L3/4 背根神经节(DRG)外植体中神经元群体同时被 CAPS 激发的情况,该小鼠在几乎所有初级感觉神经元中表达细胞质、基因编码的 Ca 传感器。使用 GraphPad Prism 9 进行峰分析,将观察到的异质和复杂的荧光信号分解为有用的、易于比较的测量值:信号数量、滞后时间、相对于基线的最大强度(Max.)和持续时间。
5 分钟暴露于 CAPS 激活了质膜 TRPV1,并导致 Ca 进入 DRG 神经元(DRGNs)引起荧光增加,这可被辣椒素或去除细胞外 Ca 所阻止。增加[CAPS](分别为 0.3、1 和 10 μM)会引起更多神经元发出信号(5 个 DRG 中的 123、275 和 390 个),平均滞后时间更短(6.4±0.4、3.3±0.2 和 1.9±0.1 分钟),持续时间更长(1.4±0.2、2.9±0.2 和 4.8±0.3 分钟)。虽然升高[CAPS]会使单个神经元的 Max.略有增加,但那些增加较大的神经元会被选择性加速;这有助于扩大反应性神经元群体的更快起始和更高峰值累积荧光。CAPS 导致许多细胞在高荧光和低荧光之间波动,连续脉冲增加 Max.和持续时间,尤其是当暴露时间从 5 分钟延长至 20 分钟时。这种信号促进作用抵消了在重复暴露于 1 μM CAPS 时观察到的脱敏作用,随着时间的推移(信号密度)在群体中保持累积荧光。
DRG 中的单个神经元对 CAPS 的反应动力学差异很大,但通过升高[CAPS]引起的系统变化以分级方式增加信号密度,揭示了对有害化学物质反应的群体编码的可能机制。尽管一些神经元存在严重的脱敏作用,但在延长和重复暴露于 CAPS 期间信号密度仍得以维持,这是通过其他神经元的信号促进作用实现的。这可以解释临床上使用 CAPS 时持续数小时的灼热感。
