小脑菱形唇系基因的遗传缺失可以通过心室区衍生祖细胞的适应性重编程来刺激代偿。

IF 4 3区 生物学 Q1 DEVELOPMENTAL BIOLOGY
Alexandre Wojcinski, Morgane Morabito, Andrew K Lawton, Daniel N Stephen, Alexandra L Joyner
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引用次数: 17

摘要

背景:小脑是脑后部叶状结构,参与运动和认知的协调。体外颗粒细胞层(EGL)中ATOH1+颗粒细胞前体(GCPs)的增殖依赖于Sonic Hedgehog (SHH)信号,这是形成小脑叶状结构和正确数量颗粒细胞的关键步骤,因此小脑在出生后经历快速生长。由于发育较晚,小脑特别容易受到早产和分娩压力的伤害。我们最近发现了发育中的小脑通过巢蛋白表达祖细胞(NEPs)的适应性重编程来补充消融的gcp的内在能力。然而,这种补偿机制是否发生在影响发育中的小脑的小鼠突变体中,并可能导致表型的错误解释尚不清楚。方法:我们使用了两种不同的方法来去除GCPs中主要的SHH信号激活因子GLI2: 1)我们使用时空重组控制(MASTR)技术进行马赛克突变分析,以删除一小部分GCPs中的GLI2;2)通过Atoh1-Cre基因在大部分EGL中删除Gli2。利用遗传诱导命运定位(GIFM)和实时成像技术分析了Gli2缺失后NEPs的行为。结果:嵌合分析表明,sh - gli2信号对于通过维持gcp处于未分化增殖状态并促进其存活来产生正确的颗粒细胞池至关重要。尽管如此,胚胎中大部分gcp中GLI2的失活并没有导致预期的成年小脑大小的急剧减少。GIFM发现NEPs确实在Gli2条件突变体中补充gcp,然后扩大并部分恢复颗粒细胞的产生。此外,SHH信号依赖的NEP补偿需要Gli2,这表明该通路的激活剂侧参与其中。结论:我们证明,导致GCPs中SHH信号缺失的小鼠条件突变不足以诱导长期严重小脑发育不全。因此,在解释影响gcp的Atoh1-Cre条件突变体的表型时,必须考虑新生儿小脑通过NEPs的反应在细胞丢失后再生的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Genetic deletion of genes in the cerebellar rhombic lip lineage can stimulate compensation through adaptive reprogramming of ventricular zone-derived progenitors.

Genetic deletion of genes in the cerebellar rhombic lip lineage can stimulate compensation through adaptive reprogramming of ventricular zone-derived progenitors.

Genetic deletion of genes in the cerebellar rhombic lip lineage can stimulate compensation through adaptive reprogramming of ventricular zone-derived progenitors.

Genetic deletion of genes in the cerebellar rhombic lip lineage can stimulate compensation through adaptive reprogramming of ventricular zone-derived progenitors.

Background: The cerebellum is a foliated posterior brain structure involved in coordination of motor movements and cognition. The cerebellum undergoes rapid growth postnataly due to Sonic Hedgehog (SHH) signaling-dependent proliferation of ATOH1+ granule cell precursors (GCPs) in the external granule cell layer (EGL), a key step for generating cerebellar foliation and the correct number of granule cells. Due to its late development, the cerebellum is particularly vulnerable to injury from preterm birth and stress around birth. We recently uncovered an intrinsic capacity of the developing cerebellum to replenish ablated GCPs via adaptive reprogramming of Nestin-expressing progenitors (NEPs). However, whether this compensation mechanism occurs in mouse mutants affecting the developing cerebellum and could lead to mis-interpretation of phenotypes was not known.

Methods: We used two different approaches to remove the main SHH signaling activator GLI2 in GCPs: 1) Our mosaic mutant analysis with spatial and temporal control of recombination (MASTR) technique to delete Gli2 in a small subset of GCPs; 2) An Atoh1-Cre transgene to delete Gli2 in most of the EGL. Genetic Inducible Fate Mapping (GIFM) and live imaging were used to analyze the behavior of NEPs after Gli2 deletion.

Results: Mosaic analysis demonstrated that SHH-GLI2 signaling is critical for generating the correct pool of granule cells by maintaining GCPs in an undifferentiated proliferative state and promoting their survival. Despite this, inactivation of GLI2 in a large proportion of GCPs in the embryo did not lead to the expected dramatic reduction in the size of the adult cerebellum. GIFM uncovered that NEPs do indeed replenish GCPs in Gli2 conditional mutants, and then expand and partially restore the production of granule cells. Furthermore, the SHH signaling-dependent NEP compensation requires Gli2, demonstrating that the activator side of the pathway is involved.

Conclusion: We demonstrate that a mouse conditional mutation that results in loss of SHH signaling in GCPs is not sufficient to induce long term severe cerebellum hypoplasia. The ability of the neonatal cerebellum to regenerate after loss of cells via a response by NEPs must therefore be considered when interpreting the phenotypes of Atoh1-Cre conditional mutants affecting GCPs.

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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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