Kurpius Dana, Wilson Nicholas, Fuller Leah, Hoffman Amara, Dailey Michael E
Department of Biological Sciences, The University of Iowa, Iowa City, 52242, USA.
Glia. 2006 Jul;54(1):58-70. doi: 10.1002/glia.20355.
Neuronal injury in CNS tissues induces a rapid activation and mobilization of resident microglia (MG). It is widely assumed that changes in gene expression drive the morphological transformation of MG and regulate their mobilization during activation. Here, we used acutely excised neonatal rat brain slices to test whether the morphological transformation and homing of MG to injured neurons requires gene expression and de novo protein synthesis. Traumatic injury during excision of live brain tissue slices induces a rapid and transient translocation of a transcription factor, NF-kappaB, to nuclei in MG. This is followed within 4-8 h by an increase in immunolabeling for cell adhesion molecules and lysosomal proteins, accompanied by changes in cell morphology. Application of anisomycin, a protein synthesis inhibitor, prevents the increase in immunolabeling for markers of MG activation but not the morphological transformation. Confocal time-lapse imaging in live tissue slices indicates that MG cell motility (branch extension and retraction) and locomotion are unaffected by anisomycin at early postinjury time-points (<4 h), while at later time-points (4-8 h postinjury) MG locomotion but not motility is inhibited. Thus, activated MG rapidly localize to injured pyramidal neuron cell bodies by 4-h postinjury, even in the presence of anisomycin. Moreover, this early MG activation and homing to injured neurons is unaffected in tissue slices from beta2 integrin deficient mice. These results indicate that gene activation and new protein synthesis coincide with, but are not necessary for, the rapid morphological transformation and early migration-dependent homing of activated MG to injured neurons in CNS tissues.
中枢神经系统组织中的神经元损伤会迅速激活并动员驻留的小胶质细胞(MG)。人们普遍认为基因表达的变化驱动了小胶质细胞的形态转变,并在激活过程中调节其动员。在这里,我们使用急性切除的新生大鼠脑片来测试小胶质细胞的形态转变以及向损伤神经元的归巢是否需要基因表达和从头合成蛋白质。在切除活脑组织切片过程中的创伤性损伤会诱导一种转录因子NF-κB迅速且短暂地转位至小胶质细胞的细胞核。在4-8小时内,随之而来的是细胞黏附分子和溶酶体蛋白免疫标记的增加,并伴有细胞形态的变化。应用蛋白质合成抑制剂茴香霉素可阻止小胶质细胞激活标志物免疫标记的增加,但不影响形态转变。活组织切片中的共聚焦延时成像表明,在损伤后早期时间点(<4小时),茴香霉素不影响小胶质细胞的运动性(分支延伸和回缩)和移动,而在后期时间点(损伤后4-8小时),茴香霉素抑制小胶质细胞的移动但不影响运动性。因此,即使存在茴香霉素,激活的小胶质细胞在损伤后4小时内也会迅速定位于损伤的锥体神经元细胞体。此外,在β2整合素缺陷小鼠的组织切片中,这种早期小胶质细胞的激活和向损伤神经元的归巢不受影响。这些结果表明,基因激活和新蛋白质合成与激活的小胶质细胞在中枢神经系统组织中向损伤神经元的快速形态转变和早期迁移依赖性归巢同时发生,但并非其必需条件。
