Takahashi N, Kikuchi S, Dai Y, Kobayashi K, Fukuoka T, Noguchi K
Department of Anatomy and Neuroscience, Hyogo college of Medicine, 1-1 Mukogawa-cho, Nishinomiya City, Hyogo 663-8501, Japan.
Neuroscience. 2003;121(2):441-50. doi: 10.1016/s0306-4522(03)00432-9.
Multiple voltage-gated sodium channels are the primary mediators of cell excitability. They are multimers that consist of the pore-forming alpha subunit and auxiliary beta subunits. Although ion permeability and voltage sensing are primarily determined by the alpha subunit, beta subunits are important modulators of sodium channel function. The purpose of this study was to assess the effect of axotomy on the expression of beta subunits (beta(1), beta(2) and beta(3)) and coexpression of Na(v)1.3 and beta(3) subunits in the dorsal root ganglion (DRG). We used sciatic nerve transection models or spared nerve injury (SNI) models in the rat. In reverse transcriptase-polymerase chain reaction analysis, there were no significant differences between contralateral and ipsilateral DRGs of beta(1) and beta(2) mRNA 3 days after axotomy. beta(3) mRNA expression in ipsilateral DRGs increased significantly compared with contralateral DRGs 3 days after axotomy. In in situ hybridization histochemistry, beta(1) mRNA was predominantly expressed in medium- to large-size neurons, whereas beta(2) mRNA was expressed in small- to large-size neurons. There were no significant differences in beta(1) and beta(2) mRNA between contralateral and ipsilateral DRGs 3 days after axotomy. In contrast, beta(3) mRNA was mainly expressed in small neurons and occasionally in medium- to large-size neurons, and beta(3) mRNA expression in small c-type neurons in ipsilateral DRGs was increased significantly compared with contralateral DRGs. We examined beta(3) mRNA expression with one of alpha subunits, Na(v)1.3-ir, in DRG neurons after axotomy using the double labeling method. We found a high percentage of coexpression in injured DRG neurons: 83.6+/-2.8% of neurons expressing beta(3) mRNA were labeled for Na(v)1.3-ir; 70.1+/-3.1% of Na(v)1.3-ir neurons expressed beta(3) mRNA. We also examined the expression of beta(3) mRNA in DRG neurons in the SNI model, a neuropathic pain model. We used activating transcription factor 3 to identify axotomized neurons, and found that beta(3) mRNA up-regulation occurred mainly in axotomized neurons in the neuropathic pain model. These data strongly suggest that beta(3) expression in injured DRG neurons following axotomy might be an important pathomechanism of post-nerve injury pain in primary sensory neurons.
多种电压门控性钠通道是细胞兴奋性的主要介质。它们是由形成孔道的α亚基和辅助性β亚基组成的多聚体。尽管离子通透性和电压感应主要由α亚基决定,但β亚基是钠通道功能的重要调节因子。本研究的目的是评估轴突切断术对背根神经节(DRG)中β亚基(β(1)、β(2)和β(3))表达以及Na(v)1.3和β(3)亚基共表达的影响。我们在大鼠中使用坐骨神经横断模型或保留神经损伤(SNI)模型。在逆转录聚合酶链反应分析中,轴突切断术后3天对侧和同侧DRG中β(1)和β(2) mRNA无显著差异。轴突切断术后3天,同侧DRG中β(3) mRNA表达与对侧DRG相比显著增加。在原位杂交组织化学中,β(1) mRNA主要在中大型神经元中表达,而β(2) mRNA在小至大型神经元中表达。轴突切断术后3天,对侧和同侧DRG中β(1)和β(2) mRNA无显著差异。相反,β(3) mRNA主要在小神经元中表达,偶尔在中大型神经元中表达,同侧DRG中小c型神经元中β(3) mRNA表达与对侧DRG相比显著增加。我们使用双标法在轴突切断术后的DRG神经元中检测β(3) mRNA与α亚基之一Na(v)1.3免疫反应性(Na(v)1.3-ir)的共表达。我们发现在受损的DRG神经元中共表达比例很高:表达β(3) mRNA的神经元中有83.6±2.8%被标记为Na(v)1.3-ir;Na(v)1.3-ir神经元中有70.1±3.1%表达β(3) mRNA。我们还在神经性疼痛模型SNI模型中检测了DRG神经元中β(3) mRNA的表达。我们使用激活转录因子3来识别轴突切断的神经元,发现β(3) mRNA上调主要发生在神经性疼痛模型中的轴突切断神经元中。这些数据强烈表明,轴突切断术后受损DRG神经元中β(3)的表达可能是初级感觉神经元神经损伤后疼痛的重要病理机制。
