Koeppen A H, Dickson A C, Chu R C, Thach R E
Neurology Service, VA Medical Center, Albany, NY 12208.
Ann Neurol. 1993 Nov;34(5):646-53. doi: 10.1002/ana.410340505.
In advanced cases of superficial siderosis of the human central nervous system, the clinical triad of hearing loss, cerebellar ataxia, and myelopathy permits the diagnosis at the bedside, and magnetic resonance imaging readily confirms the hemosiderin deposits in brainstem, cerebellum, and spinal cord. To study the pathogenesis of this condition and explain the selective vulnerability of the cerebellum, experimental siderosis was induced in rabbits by the repeated intracisternal injection of autologous red blood cells. The earliest cellular response in the cerebellar molecular layer was hyperplasia and hypertrophy of microglia as displayed by immunocytochemistry for ferritin. Microglia also contained iron, but ferritin biosynthesis appeared to proceed without commensurate iron accumulation. This early apoferritin response probably occurred due to the presence of heme, rather than iron, in the cerebrospinal fluid and subpial tissue. Ferritin biosynthesis is accelerated when the ferritin repressor protein is dissociated from ferritin messenger ribonucleic acid. A specific antiserum localized ferritin repressor protein predominantly to astrocytes including Bergmann glia. It is proposed that abundance and proximity of ferritin repressor protein--immunoreactive Bergmann glia and ferritin-containing microglia in the cerebellar molecular layer permit prompt cellular interaction in the conversion of heme to ferritin and ultimately hemosiderin.
在人类中枢神经系统浅表性铁沉积症的晚期病例中,听力丧失、小脑共济失调和脊髓病这一临床三联征有助于床边诊断,磁共振成像也能轻易证实脑干、小脑和脊髓中的含铁血黄素沉积。为了研究这种病症的发病机制并解释小脑的选择性易损性,通过反复脑池内注射自体红细胞在兔子身上诱发实验性铁沉积症。小脑分子层最早的细胞反应是小胶质细胞增生和肥大,这通过铁蛋白免疫细胞化学得以显示。小胶质细胞也含有铁,但铁蛋白生物合成似乎在没有相应铁积累的情况下进行。这种早期的脱铁铁蛋白反应可能是由于脑脊液和软脑膜组织中存在血红素而非铁所致。当铁蛋白阻遏蛋白与铁蛋白信使核糖核酸解离时,铁蛋白生物合成会加速。一种特异性抗血清将铁蛋白阻遏蛋白主要定位于包括伯格曼胶质细胞在内的星形胶质细胞。有人提出,小脑分子层中铁蛋白阻遏蛋白免疫反应性伯格曼胶质细胞和含铁小胶质细胞的数量及接近程度,使得在血红素转化为铁蛋白并最终转化为含铁血黄素的过程中能够迅速进行细胞间相互作用。