呼吸系统同步病毒病毒特定核胶囊的生成和组装
Summary
为了深入分析呼吸道同步病毒 (RSV) RNA 合成,我们报告了利用伴生磷蛋白 (P) 共同表达无RNA核蛋白 (N0)的协议,用于病毒特定核胶囊 (NCs) 的后续 体外 组装。
Abstract
使用正宗的RNA模板对于推进病毒RNA合成的基本知识至关重要,该知识可以指导机械发现和病毒学的检测发展。非受教负感 (NNS) RNA 病毒(如呼吸道同步病毒 (RSV))的 RNA 模板不是单单 RNA 分子,而是核蛋白 (N) 封装核糖核蛋白复合物。尽管正宗RNA模板很重要,但这种核糖核蛋白复合物的生成和组装仍然复杂,需要深入阐明。主要的挑战是,过度表达的RSV N非具体地与细胞RNA结合,形成随机核胶囊状粒子(NCLPs)。在这里,我们建立了一个协议,通过与伴郎磷蛋白 (P) 共同表达 N,然后用 RNA 寡头与 RSV 特异性 RNA 序列组装 N0来获得无RNA N (N0),以获得病毒特异性核胶囊 (NCs)。该协议展示了如何克服在准备这个传统上具有挑战性的病毒核糖蛋白复合物的困难。
Introduction
非隔离性负感(NNS)RNA病毒包括许多重要的人类病原体,如狂犬病、埃博拉和呼吸道同步病毒(RSV)1、2。RSV是导致全球幼儿和老年人患支气管炎和肺炎等呼吸系统疾病的主要原因。目前,没有有效的疫苗或抗病毒疗法可用于预防或治疗RSV4。作为生命周期的一部分,RSV基因组作为RSV RNA依赖RNA聚合酶复制的模板,以产生抗原体,而抗基因组又充当生成后代基因组的模板。基因组和抗基因组RNA都完全被核蛋白(N)封装,形成核胶囊(NCs)3。由于NC是RSV聚合酶复制和转录的模板,因此适当的NC组装对于聚合酶获得RNA合成5的模板至关重要。有趣的是,根据NNS病毒聚合酶的结构分析,假设几个N蛋白暂时脱离NC,允许聚合酶进入,并在RNA合成6、7、8、9、10、11、12后重新绑定RNA。
目前,RSV RNA聚合检测已建立使用纯化RSV聚合酶短裸RNA模板13,14。然而,RSV聚合酶的活动没有达到最佳水平,正如RSV聚合酶在使用裸RNA模板时产生的非加工和流产产品中观察到的。缺乏带有病毒特异性RNA的NC是进一步机械化地理解RSV RNA合成的主要障碍。因此,使用正宗的RNA模板成为推进RSV RNA合成基础知识的关键需要。来自RSV和其他NNS RNA病毒的核胶囊状粒子(NCLPs)的已知结构显示,NCLP中的RNA要么是随机细胞RNA,要么是平均病毒基因组RNA15、16、17、18、19。总之,主要障碍是,当N在主机单元中表达过度时,N与细胞RNA结合,形成NCLP。
为了克服这一障碍,我们建立了一个协议,首先获得无RNA(N0),并组装N0 与正宗的病毒基因组RNA到NCLP20。该协议的原则是获得大量的重组RNA无N(N0)通过共同表达N与伴郎,RSV磷蛋白(PNTD)的N终端域。纯化的 N0P 可以通过添加 RSV 特异性 RNA 寡头来刺激并组装成 NCLP,在组装过程中,伴郎 PNTD 在添加 RNA 寡头后会被移位。
在这里,我们详细说明了 RSV 特定 RNA 特定 NC 的生成和组装协议。在此协议中,我们描述了分子克隆、蛋白质制备、 体外 组装和复杂组件的验证。我们强调克隆策略,为分子克隆的蛋白质共表达生成双柠檬结构。在蛋白质制备方面,我们描述了细胞培养、蛋白质提取和蛋白质复合物的纯化过程。然后,我们讨论RSV RNA特定NC的 体外 组装方法。最后,我们使用大小排除色谱 (SEC) 和负污渍电子显微镜 (EM) 来描述和可视化组装的 NCLP。
Protocol
1. 分子克隆 注:利气独立克隆(LIC)用于制造RSV双语气联表达构造质粒。LIC是一种在20世纪90年代初开发的方法,它利用T4DNA聚合酶的3′-5’Exo活性来制造载体和DNA插入21,22之间的互补性悬垂。构造使用 2BT-10 矢量 DNA 进行,该 DNA 由他在开放读取帧 (ORF) (图 1)N 端的标记组成。 使用 SSPI ?…
Representative Results
无RNA N0P蛋白的纯化通过此协议,可以获得大规模可溶性异质 RSV N0P 复合体。P蛋白的N和N终端部分的全长与大肠杆菌中的N蛋白的10倍共同表达。N0P 使用钴柱、离子交换和大小排除色谱进行纯化。N0P 包含全长 N 端和 N 端 P,但不包含基于紫外线吸收 A260 /A 280比率20 (图4)的蜂窝RNA。 <p class="jove_…
Discussion
已知的核胶囊状粒子(NCLP)结构的非隔离负感(NNS)RNA病毒表明,组装的NCLP是复杂的N与宿主细胞RNA时,过度表达在细菌或真核表达系统15,16,17,18,19。先前的研究已经尝试通过各种方法获得RNA免费N,如RNA酶A消化,高盐洗涤,或调整不同的pH缓冲器,以去除非特异性细胞…
Divulgaciones
The authors have nothing to disclose.
Acknowledgements
埃默里梁实验室的研究项目由美国国家普通医学科学研究院 (NIGMS)、国家卫生研究院 (NIH) 提供,奖励编号为 R01GM130950,以及埃默里大学医学院的研究启动基金。作者感谢梁实验室的成员给予的帮助和支持和批判性讨论。
Materials
| Agarose | SIgma | A9539-500G | making construct using LIC method |
| Amicon Ultra-15 Centrifugal Filter Unit | Millipore | UFC901024 | concentrate the protein sample |
| Ampicillin sodium | GOLD BIOTECHNOLOGY | 5118.111317A | antibiotic for cell culture |
| AseI | NEB | R0526S | making construct using LIC method |
| Cobalt (High Density) Agarose Beads | Gold Bio | H-310-500 | For purification of His-tag protein |
| Corning LSE Digital Dry Bath Heater | CORNING | 6885-DB | Heate the sample |
| dCTP | Invitrogen | 10217016 | making construct using LIC method |
| dGTP | Invitrogen | 10218014 | making construct using LIC method |
| Glycerol | Sigma | G5516-4L | making solution |
| HEPES | Sigma | H3375-100G | making solution |
| HiTrap Q HP | Sigma | GE29-0513-25 | Protein purification |
| Imidazole | Sigma | I5513-100G | making solution |
| IPTG (Isopropyl-beta-D-thiogalactopyranoside) | GOLD BIOTECHNOLOGY | 1116.071717A | induce the expression of protein |
| Microcentrifuge Tubes | VWR | 47730-598 | for PCR |
| Misonix Sonicator XL2020 Ultrasonic Liquid Processor | SpectraLab | MSX-XL-2020 | sonicator for lysing cell |
| Negative stain grids | Electron Microscopy Sciences | CF400-Cu-TH | For making negative stain grids |
| New Brunswick Innova 44/44R | eppendorf | M1282-0000 | Shaker for culturing the cell |
| Nonidet P 40 Substitute | Sigma | 74385-1L | making solution |
| OneTaq DNA Polymerase | NEB | M0480L | PCR |
| QIAquick Gel Extraction Kit | QIAGEN | 28706 | Purify DNA |
| SSPI-HF | NEB | R3132S | making construct using LIC method |
| Superose 6 Increase 10/300 GL | Sigma | GE29-0915-96 | Protein purification |
| T4 DNA polymerase | Sigma | 70099-3 | making construct using LIC method |
| Thermo Scientific Sorvall RC 6 Plus Centrifuge | Fisher Scientific | 36-101-0816 | Centrifuge, highest speed 20,000 rpm |
| Trizma hydrochloride | Sigma | T3253-250G | making solution |
| Uranyl Formate | Electron Microscopy Sciences | 22451 | making negative stain solution |
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Citar este artículo
Gao, Y., Ogilvie, C., Raghavan, A., Von Hoffmann, C., Liang, B. Generation and Assembly of Virus-Specific Nucleocapsids of the Respiratory Syncytial Virus. J. Vis. Exp. (173), e62010, doi:10.3791/62010 (2021).