莱因哈蒂衣原体中去膜化细胞模型的再激活
Summary
运动细胞的 体外 再激活是了解细胞运动机制的关键实验。该协议描述了重新激活 衣原体莱因哈蒂衣原体的去膜化细胞模型,这是一种研究纤毛/鞭毛的模式生物。
Abstract
自从Szent-Györgyi在20世纪中叶证明的通过添加ATP来收缩甘油化肌肉的历史实验以来,去膜化细胞的体外再激活一直是检查细胞运动的传统而有效的方法。这种实验方法的根本优点是再活化溶液的组成可以很容易地改变。例如,由于体内膜激发而仅暂时发生的高Ca2 +浓度环境可以在实验室中复制。真核纤毛(又名鞭毛)是精心设计的运动机制,其调节机制仍有待澄清。单细胞绿藻衣原体是纤毛研究领域的优秀模式生物。使用C. reinhardtii的去膜化细胞模型及其衍生物(例如分离的纤毛的去膜化轴突)的再激活实验对理解纤毛运动的分子机制有显着贡献。这些实验澄清了ATP为纤毛运动提供能量,并且各种细胞信号,包括Ca2 +,cAMP和活性氧,调节纤毛运动。这里描述了C. reinhardtii细胞的去膜和细胞模型的再激活的精确方法。
Introduction
去膜运动细胞的体外再活化是研究细胞运动调节机制的分子基础的宝贵工具。Szent-Györgyi首先通过添加三磷酸腺苷(ATP)1,首次证明了用50%甘油提取的兔骨骼肌纤维的体外收缩。这个实验是第一个证明ATP为肌肉收缩提供能量的实验。该方法很快被应用于ATP激励的睫状/鞭毛运动的研究,例如精子鞭毛2,纤毛副膜3和克莱因哈蒂环状衣原体(也称为鞭毛)4,使用非离子洗涤剂进行去膜化。
单细胞绿藻 C. reinhardtii 是研究纤毛的模式生物:它通过像人类的蛙泳一样击败它们来与两个纤毛一起游泳5。纤毛运动由动力蛋白驱动,动力蛋白是一种基于负端定向微管的运动蛋白6,7。睫状动力素可分为外臂动力蛋白和内臂动力蛋白。缺乏每种动力蛋白的突变体已被分离为具有不同运动异常的慢游突变体。对这些突变体的详细 体外 运动性分析显著推动了动力蛋白研究8.
自去膜化C. reinhardtii细胞(细胞模型)的体外再活化实验以来,利用该方法及其衍生物已经取得了许多重要发现。例如,在一系列Ca2 +缓冲液中重新激活细胞模型,表明9表明两个纤毛受亚微摩尔Ca2 +的不同调控,并且这种不对称的纤毛控制使C. reinhardtii10的光定向成为可能。此外,纤毛都显示从前向游动模式(称为非对称波形)到向后游动模式(称为对称波形,在细胞被光或机械电击时短时间内出现)的波形转换11,12。这种波形转换由亚毫摩尔Ca2+调节,其通过所谓的细胞核细胞核装置(包含两个纤毛,基底体,连接基体的结构以及细胞核的残余物)11或分离纤毛13的去膜化轴突的重新激活来显示。除Ca2 +外,氧化还原(还原氧化)是一种调节纤毛跳动频率的信号,这通过在含有不同比例的还原谷胱甘肽与氧化谷胱甘肽14的氧化还原缓冲液中重新激活细胞模型来显示。此外,环磷酸腺苷(cAMP)不对称地调节两个纤毛,这表现为用光裂笼笼cAMP15重新激活轴突。这些体外发现,结合遗传学发现,使人们更深入地了解了C. reinhardtii纤毛调节的分子机制。
此处描述了用于重新激活单元模型的协议。该方法很简单,允许各种修饰,并且可以应用于与纤毛一起移动的多个生物体。然而,由于去膜化细胞是脆弱的,因此需要一些技巧才能以良好的效率重新激活细胞模型的运动性,同时防止分升。
Protocol
Representative Results
Discussion
该协议中有两个关键步骤。第一种是称为去膜的过程,需要温和但彻底地进行。通过剧烈移液或涡旋诱导分化(即纤毛从细胞体中分离),即使在添加ATP后,细胞模型也无法移动。通常,将5×10个7 个细胞悬浮在〜0.5mL的去膜缓冲液中(最终细胞密度:1×108 个细胞/ mL)。如果细胞模型密度远低于此值(例如,1个×10个6 个细胞/mL),则细胞模型的再激活率将降低。这些细胞?…
Offenlegungen
The authors have nothing to disclose.
Acknowledgements
本研究得到了日本科学促进会KAKENHI(https://www.jsps.go.jp/english/index.html)对N.U.(19K23758,21K06295)和K.W.(19H03242,20K21420,21H00420),Ohsumi Frontier Science Foundation(https://www.ofsf.or.jp/en/)到K.W.的资助,以及来自人类,环境和材料(http://alliance.tagen.tohoku.ac.jp/english/)与N.U.和K.W.的开放式创新动态联盟的支持。我们感谢筱原美雪女士(法政大学)在准备这些数字时给予的帮助。
Materials
| 0.5 mL plastic tube | QSP | 502-PLN-Q | |
| 15 mL conical tube | SARSTEDT | 62.554.502 | |
| Adenosine 5'-triphosphate disodium salt hydrate (ATP) | Sima-Aldrich | A2383 | |
| Centrifuge | KUBOTA | 2800 | |
| Chlamydomonas strain CC-125 | Chlamydomonas Resource Center | https://www.chlamycollection.org/ | |
| Creatine kinase | Merck | CK-RO | |
| Creatine phosphate | Merck | CRPHO-RO | |
| Dithiothreitol (DTT) | Nakalai tesque | 14128-46 | |
| GEDTA(EGTA) | Dojindo | G002 | |
| Hepes | Dojindo | GB70 | |
| Igepal CA-630 | Sigma-Aldrich | I8896 | IUPAC name is octylphenoxypolyethoxyethanol: IGEPAL CA-630 is a substitute for Nonidet P-40 (NP-40); NP-40 is no longer available in Sigma-Aldrich. |
| MgSO4-7H2O | Nakalai tesque | 21002-85 | |
| Microscope | Olympus | BX-53 | |
| Pasteur pipette | fisher scientific | 13-678-20C | |
| Polyethylene glycol, Mr 20,000 | Merck | 8.18897.1000 | |
| Pottasium acetate | Nakalai tesque | 28434-25 | |
| Sodium Hydroxide | Nacalai | 31511-05 | |
| Sucrose | FUJIFILM Wako Pure Chemical Corporation | 196-00015 |
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