Centro FONDAP de Estudios Moleculares de la Célula, Universidad de Chile, Independencia 1027, Santiago, Chile.
Neurotox Res. 2010 Apr;17(3):238-47. doi: 10.1007/s12640-009-9096-z. Epub 2009 Aug 5.
Iron is essential for crucial neuronal functions but is also highly toxic in excess. Neurons acquire iron through transferrin receptor-mediated endocytosis and via the divalent metal transporter 1 (DMT1). The N-terminus (1A, 1B) and C-terminus (+IRE, -IRE) splice variants of DMT1 originate four protein isoforms, all of which supply iron to cells. Diverse physiological or pathological conditions induce differential DMT1 variant expression, which are cell-type dependent. Hence, it becomes relevant to ascertain if activation of neuronal plasticity processes that require functional N-methyl D: -aspartate (NMDA) receptors, including in vitro stimulation of NMDA receptor-mediated signaling and spatial memory training, selectively modify DMT1 variant expression. Here, we report for the first time that brief (5 min) exposure of primary hippocampal cultures to NMDA (50 muM) increased 24 h later the expression of DMT1-1B and DMT1+IRE, but not of DMT1-IRE mRNA. In contrast, endogenous DMT1 mRNA levels remained unaffected following 6 h incubation with brain-derived nerve factor. NMDA (25-50 muM) also enhanced DMT1 protein expression 24-48 h later; this enhancement was abolished by the transcription inhibitor actinomycin D and by the NMDA receptor antagonist MK-801, implicating NMDA receptors in de novo DMT1 expression. Additionally, spatial memory training enhanced DMT1-1B and DMT1+IRE expression and increased DMT1 protein content in rat hippocampus, where the exon1A variant was not found. These results suggest that NMDA receptor-dependent plasticity processes stimulate expression of the iron transporter DMT1-1B+IRE isoform, which presumably plays a significant role in hippocampal spatial memory formation.
铁对于关键的神经元功能至关重要,但过量也会产生高度毒性。神经元通过转铁蛋白受体介导的内吞作用和二价金属转运蛋白 1(DMT1)摄取铁。DMT1 的 N 端(1A、1B)和 C 端(+IRE、-IRE)剪接变体产生四种蛋白质同工型,它们都为细胞提供铁。不同的生理或病理条件诱导不同的 DMT1 变体表达,这依赖于细胞类型。因此,确定是否激活需要功能性 N-甲基-D-天冬氨酸(NMDA)受体的神经元可塑性过程变得很重要,包括 NMDA 受体介导的信号转导的体外刺激和空间记忆训练,这些过程选择性地改变 DMT1 变体表达。在这里,我们首次报道,原代海马培养物短暂(5 分钟)暴露于 NMDA(50 μM)会在 24 小时后增加 DMT1-1B 和 DMT1+IRE 的表达,但不增加 DMT1-IRE mRNA 的表达。相比之下,内源性 DMT1 mRNA 水平在 6 小时孵育脑源性神经营养因子后不受影响。NMDA(25-50 μM)也会在 24-48 小时后增强 DMT1 蛋白表达;该增强作用被转录抑制剂放线菌素 D 和 NMDA 受体拮抗剂 MK-801 所阻断,表明 NMDA 受体参与了 DMT1 的从头表达。此外,空间记忆训练会增强 DMT1-1B 和 DMT1+IRE 的表达,并增加大鼠海马中的 DMT1 蛋白含量,而在海马中没有发现外显子 1A 变体。这些结果表明,NMDA 受体依赖性可塑性过程刺激铁转运蛋白 DMT1-1B+IRE 同工型的表达,这可能在海马空间记忆形成中发挥重要作用。
