Kleopa Kleopas A, Elman Lauren B, Lang Bethan, Vincent Angela, Scherer Steven S
Department of Clinical Neurosciences, Cyprus Institute of Neurology and Genetics, Nicosia, Cyprus, PA, USA.
Brain. 2006 Jun;129(Pt 6):1570-84. doi: 10.1093/brain/awl084. Epub 2006 Apr 13.
Autoantibodies to Shaker-type (Kv1) K+ channels are now known to be associated with three syndromes. Peripheral nerve hyperexcitability is the chief manifestation of acquired neuromyotonia; the combination of neuromyotonia with autonomic and CNS involvement is called Morvan's syndrome (MoS); and CNS manifestations without peripheral involvement is called limbic encephalitis (LE). To determine the cellular basis of these clinical manifestations, we immunostained mouse neural tissues with sera from patients with neuromyotonia (n = 10), MoS (n = 2) or LE (n = 5), comparing with specific antibodies to relevant K+ channel subunits. Fourteen of 17 patients' sera were positive for Kv1.1, Kv1.2 or Kv1.6 antibodies by immunoprecipitation of 125I-alpha-dendrotoxin-labelled rabbit brain K+ channels. Most sera (11 out of 17) labelled juxtaparanodes of peripheral myelinated axons, co-localizing with Kv1.1 and Kv1.2. In the CNS, all sera tested (n = 12) co-localized with one or more areas of high Kv1.1, Kv1.2 or Kv1.6 channel expression: 10 out of 12 sera co-localized with Kv1.1 and Kv1.2 at spinal cord juxtaparanodes or cerebellar layers, while 3 out of 12 sera co-localized additionally (n = 2) or exclusively (n = 1) with Kv1.6 subunits in Purkinje cells, motor and hippocampal neurons. However, only sera from LE patients labelled the hippocampal areas that are enriched in excitatory, Kv1.1-positive axon terminals. All sera (17 out of 17) labelled one or more of these Kv1 subunits when expressed at the cell membrane of transfected HeLa cells, but not when they were retained in the endoplasmic reticulum. Again, LE sera labelled Kv1.1 subunits more prominently than did MoS or neuromyotonia sera, suggesting an association between higher Kv1.1 specificity and limbic manifestations. In contrast, neuromyotonia sera bound more strongly to Kv1.2 subunits than to Kv1.1 or Kv1.6. These studies support the hypothesis that antibodies to mature surface membrane-expressed Shaker-type K+ channels cause acquired neuromyotonia, MoS and LE, and suggest that future assays based on immunofluorescence of cells expressing individual Kv1 subunits will prove more sensitive than the immunoprecipitation assay. Although more than one type of antibody is often detectable in individual sera, higher affinity for certain subunits or subunit combinations may determine the range of clinical manifestations.
现已发现,针对震颤型(Kv1)钾通道的自身抗体与三种综合征相关。周围神经兴奋性过高是获得性神经性肌强直的主要表现;神经性肌强直合并自主神经和中枢神经系统受累被称为莫旺综合征(MoS);无周围神经受累的中枢神经系统表现被称为边缘叶脑炎(LE)。为了确定这些临床表现的细胞基础,我们用神经性肌强直患者(n = 10)、MoS患者(n = 2)或LE患者(n = 5)的血清对小鼠神经组织进行免疫染色,并与相关钾通道亚基的特异性抗体进行比较。通过对125I-α-树眼镜蛇毒素标记的兔脑钾通道进行免疫沉淀,17例患者血清中有14例对Kv1.1、Kv1.2或Kv1.6抗体呈阳性。大多数血清(17例中的11例)标记了周围有髓轴突的旁结,与Kv1.1和Kv1.2共定位。在中枢神经系统中,所有检测的血清(n = 12)都与Kv1.1、Kv1.2或Kv1.6通道高表达的一个或多个区域共定位:12例血清中的10例在脊髓旁结或小脑层与Kv1.1和Kv1.2共定位,而12例血清中的3例在浦肯野细胞、运动神经元和海马神经元中额外(n = 2)或仅(n = 1)与Kv1.6亚基共定位。然而,只有LE患者的血清标记了富含兴奋性、Kv1.1阳性轴突终末的海马区域。所有血清(17例中的17例)在转染的HeLa细胞膜上表达时都标记了这些Kv1亚基中的一种或多种,但在内质网中保留时则未标记。同样,LE血清比MoS或神经性肌强直血清更显著地标记Kv1.1亚基,表明较高的Kv1.1特异性与边缘叶表现之间存在关联。相比之下,神经性肌强直血清与Kv1.2亚基的结合比与Kv1.1或Kv1.6的结合更强。这些研究支持以下假说:针对成熟表面膜表达的震颤型钾通道的抗体可导致获得性神经性肌强直、MoS和LE,并表明基于表达单个Kv1亚基的细胞免疫荧光的未来检测将比免疫沉淀检测更敏感。尽管在个体血清中通常可检测到不止一种类型的抗体,但对某些亚基或亚基组合的更高亲和力可能决定临床表现的范围。
