Lmx1b is required for the glutamatergic fates of a subset of spinal cord neurons.

IF 4 3区 生物学 Q1 DEVELOPMENTAL BIOLOGY
William C Hilinski, Jonathan R Bostrom, Samantha J England, José L Juárez-Morales, Sarah de Jager, Olivier Armant, Jessica Legradi, Uwe Strähle, Brian A Link, Katharine E Lewis
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引用次数: 13

Abstract

Background: Alterations in neurotransmitter phenotypes of specific neurons can cause imbalances in excitation and inhibition in the central nervous system (CNS), leading to diseases. Therefore, the correct specification and maintenance of neurotransmitter phenotypes is vital. As with other neuronal properties, neurotransmitter phenotypes are often specified and maintained by particular transcription factors. However, the specific molecular mechanisms and transcription factors that regulate neurotransmitter phenotypes remain largely unknown.

Methods: In this paper we use single mutant, double mutant and transgenic zebrafish embryos to elucidate the functions of Lmx1ba and Lmx1bb in the regulation of spinal cord interneuron neurotransmitter phenotypes.

Results: We demonstrate that lmx1ba and lmx1bb are both expressed in zebrafish spinal cord and that lmx1bb is expressed by both V0v cells and dI5 cells. Our functional analyses demonstrate that these transcription factors are not required for neurotransmitter fate specification at early stages of development, but that in embryos with at least two lmx1ba and/or lmx1bb mutant alleles there is a reduced number of excitatory (glutamatergic) spinal interneurons at later stages of development. In contrast, there is no change in the numbers of V0v or dI5 cells. These data suggest that lmx1b-expressing spinal neurons still form normally, but at least a subset of them lose, or do not form, their normal excitatory fates. As the reduction in glutamatergic cells is only seen at later stages of development, Lmx1b is probably required either for the maintenance of glutamatergic fates or to specify glutamatergic phenotypes of a subset of later forming neurons. Using double labeling experiments, we also show that at least some of the cells that lose their normal glutamatergic phenotype are V0v cells. Finally, we also establish that Evx1 and Evx2, two transcription factors that are required for V0v cells to acquire their excitatory neurotransmitter phenotype, are also required for lmx1ba and lmx1bb expression in these cells, suggesting that Lmx1ba and Lmx1bb act downstream of Evx1 and Evx2 in V0v cells.

Conclusions: Lmx1ba and Lmx1bb function at least partially redundantly in the spinal cord and three functional lmx1b alleles are required in zebrafish for correct numbers of excitatory spinal interneurons at later developmental stages. Taken together, our data significantly enhance our understanding of how spinal cord neurotransmitter fates are regulated.

Abstract Image

Abstract Image

Abstract Image

Lmx1b是脊髓神经元子集的谷氨酸能命运所必需的。
背景:特定神经元的神经递质表型改变可引起中枢神经系统(CNS)兴奋和抑制的失衡,从而导致疾病。因此,正确规范和维持神经递质表型是至关重要的。与其他神经元特性一样,神经递质表型通常由特定的转录因子指定和维持。然而,调节神经递质表型的具体分子机制和转录因子在很大程度上仍然未知。方法:利用单突变体、双突变体和转基因斑马鱼胚胎,研究Lmx1ba和Lmx1bb在调控脊髓间神经元神经递质表型中的作用。结果:我们证实lmx1ba和lmx1bb在斑马鱼脊髓中均有表达,lmx1bb在V0v细胞和dI5细胞中均有表达。我们的功能分析表明,在发育的早期阶段,这些转录因子并不是神经递质归宿规范所必需的,但在具有至少两个lmx1ba和/或lmx1bb突变等位基因的胚胎中,在发育的后期,兴奋性(谷氨酸能)脊髓中间神经元的数量减少。相比之下,V0v和dI5细胞的数量没有变化。这些数据表明,表达lmx1b的脊髓神经元仍能正常形成,但至少有一部分失去或不形成其正常的兴奋性命运。由于谷氨酸能细胞的减少只在发育的后期才出现,Lmx1b可能是维持谷氨酸能命运或指定后期形成神经元子集的谷氨酸能表型所必需的。通过双标记实验,我们还表明至少一些失去正常谷氨酸能表型的细胞是V0v细胞。最后,我们还发现V0v细胞获得兴奋性神经递质表型所必需的两个转录因子Evx1和Evx2在这些细胞中也是lmx1ba和lmx1bb表达所必需的,这表明lmx1ba和lmx1bb在V0v细胞中作用于Evx1和Evx2的下游。结论:Lmx1ba和Lmx1bb在脊髓中至少有部分冗余功能,并且在斑马鱼发育后期,兴奋性脊髓中间神经元的正确数量需要三个功能性lmx1b等位基因。综上所述,我们的数据显著增强了我们对脊髓神经递质命运如何调节的理解。
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来源期刊
Neural Development
Neural Development 生物-发育生物学
CiteScore
6.60
自引率
0.00%
发文量
11
审稿时长
>12 weeks
期刊介绍: Neural Development is a peer-reviewed open access, online journal, which features studies that use molecular, cellular, physiological or behavioral methods to provide novel insights into the mechanisms that underlie the formation of the nervous system. Neural Development aims to discover how the nervous system arises and acquires the abilities to sense the world and control adaptive motor output. The field includes analysis of how progenitor cells form a nervous system during embryogenesis, and how the initially formed neural circuits are shaped by experience during early postnatal life. Some studies use well-established, genetically accessible model systems, but valuable insights are also obtained from less traditional models that provide behavioral or evolutionary insights.
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