The SLC36 transporter Pathetic is required for neural stem cell proliferation and for brain growth under nutrition restriction.

IF 4 3区生物学 Q1 DEVELOPMENTAL BIOLOGY Neural Development Pub Date : 2020-08-02 DOI:10.1186/s13064-020-00148-4

Shiyun Feng, Evanthia Zacharioudaki, Kat Millen, Sarah J Bray

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Abstract

Background: Drosophila neuroblasts (NBs) are neural stem cells whose maintenance relies on Notch activity. NBs proliferate throughout larval stages to generate a large number of adult neurons. Their proliferation is protected under conditions of nutrition restriction but the mechanisms responsible are not fully understood. As amino acid transporters (Solute Carrier transporters, SLCs), such as SLC36, have important roles in coupling nutrition inputs to growth pathways, they may have a role in this process. For example, an SLC36 family transporter Pathetic (Path) that supports body size and neural dendrite growth in Drosophila, was identified as a putative Notch target in genome-wide studies. However, its role in sustaining stem cell proliferation and maintenance has not been investigated. This study aimed to investigate the function of Path in the larval NBs and to determine whether it is involved in protecting them from nutrient deprivation.

Methods: The expression and regulation of Path in the Drosophila larval brain was analysed using a GFP knock-in allele and reporter genes containing putative Notch regulated enhancers. Path function in NB proliferation and overall brain growth was investigated under different nutrition conditions by depleting it from specific cell types in the CNS, using mitotic recombination to generate mutant clones or by directed RNA-interference.

Results: Path is expressed in both NBs and glial cells in the Drosophila CNS. In NBs, path is directly targeted by Notch signalling via Su(H) binding at an intronic enhancer, PathNRE. This enhancer is responsive to Notch regulation both in cell lines and in vivo. Loss of path in neural stem cells delayed proliferation, consistent with it having a role in NB maintenance. Expression from pathNRE was compromised in conditions of amino acid deprivation although other Notch regulated enhancers are unaffected. However, NB-expressed Path was not required for brain sparing under amino acid deprivation. Instead, it appears that Path is important in glial cells to help protect brain growth under conditions of nutrient restriction.

Conclusions: We identify a novel Notch target gene path that is required in NBs for neural stem cell proliferation, while in glia it protects brain growth under nutrition restriction.

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在营养限制条件下，神经干细胞增殖和大脑生长都需要 SLC36 转运体 Pathetic。

背景果蝇神经母细胞（NBs）是一种神经干细胞，其维持依赖于 Notch 活性。神经母细胞在整个幼虫阶段都在增殖，以产生大量的成体神经元。在营养限制条件下，它们的增殖受到保护，但其机制尚不完全清楚。由于氨基酸转运体（溶质载体转运体，SLCs）（如 SLC36）在将营养输入与生长途径耦合方面具有重要作用，因此它们可能在这一过程中发挥作用。例如，SLC36家族的转运体Pathetic（Path）支持果蝇的体型和神经树突的生长，在全基因组研究中被确定为Notch的假定靶标。然而，它在维持干细胞增殖和维护方面的作用尚未得到研究。本研究旨在调查 Path 在幼虫 NBs 中的功能，并确定它是否参与保护 NBs 免受营养剥夺：方法：利用GFP基因敲入等位基因和含有Notch调控增强子的报告基因分析了Path在果蝇幼虫大脑中的表达和调控。在不同的营养条件下，通过从中枢神经系统的特定细胞类型中清除 Path，利用有丝分裂重组产生突变克隆，或通过定向 RNA 干扰，研究了 Path 在 NB 增殖和大脑整体生长中的功能：结果：果蝇中枢神经系统中的NB和神经胶质细胞都表达Path。在NBs中，Notch信号通过Su（H）与内含子增强子PathNRE结合，直接靶向Path。该增强子在细胞系和体内都对Notch调控有反应。神经干细胞中path的缺失会延迟增殖，这与它在NB维持中的作用一致。在氨基酸缺乏的条件下，pathNRE的表达受到影响，尽管其他Notch调控增强子不受影响。然而，在氨基酸匮乏条件下，NB表达的Path并不是大脑疏通所必需的。相反，Path 在神经胶质细胞中似乎很重要，有助于在营养限制条件下保护大脑生长：我们发现了一种新的Notch靶基因路径，它在NB中是神经干细胞增殖所必需的，而在神经胶质中则能在营养限制条件下保护大脑生长。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neural Development 生物-发育生物学

CiteScore

6.60

自引率

0.00%

发文量

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.