| Preparation of a Bacteriophage T4-based Prokaryotic-eukaryotic Hybrid Viral Vector for Delivery of Large Cargos of Genes and Proteins into Human Cells
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Author:
Date:
2020-04-05
[Abstract] A viral vector that can safely and efficiently deliver large and diverse molecular cargos into cells is the holy grail of curing many human diseases. Adeno-associated virus (AAV) has been extensively used but has a very small capacity. The prokaryotic virus T4 has a large capacity but lacks natural mechanisms to enter mammalian cells. Here, we created a hybrid vector by combining T4 and AAV into one nanoparticle that possesses the advantages of both. The small 25 nm AAV particles are attached to the large 120 nm x 86 nm T4 head through avidin-biotin cross-bridges using the phage decoration proteins Soc (small outer capsid protein) and Hoc (highly antigenic outer capsid protein). AAV thus “piggy-backed” on T4 capsid, by virtue of its natural ability to enter many types of human cells ...
[摘要] [摘要 ] 一种病毒载体,可以安全有效地将大量多样的分子货物运送到细胞中 是治愈许多人类疾病的圣杯。腺伴随病毒(AAV)已被广泛使用,但容量很小。T4原核病毒容量大,但缺乏进入哺乳动物细胞的天然机制。在这里,我们通过将T4和AAV结合到一个具有两者优势的纳米颗粒中,创建了一种杂交载体。使用噬菌体修饰蛋白Soc(小的外衣壳蛋白)和Hoc(高度抗原化的外衣壳蛋白),通过亲和素-生物素交叉桥将25 nm的AAV小颗粒连接到120 nm x 86 nm的大T4头上。因此,AAV凭借其固有的进入多种类型人体细胞的自然能力,可以“背负”于T4衣壳上,从而有效地充当了“驱动器”,以运送与T4头相关的大型货物。这种独特的T4-AAV杂交载体方法可为将来开发新型疗法铺平道路。
[背景 ] 已经有新的和有效的递送载体能够运输基因和蛋白质的大货物进入人类细胞,以刺激生产治疗性生物分子的和/或修复的细胞和遗传缺陷的迫切需要。这样的载体将允许将快速出现的技术(例如CRISPR,CAR T细胞等)转化为用于大规模应用以及个性化医学的疗法(Stewart 等,2016)。
将具有不同特性的纳米粒子组装到杂化复合物中是开发新型功能材料的有力策略,因为这些杂化复合物显示出集体和协作的属性,其中某些属性可能与单个粒子所显示的属性不同(Ghosh 等人,2012; ...
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| Dual Fluorescence Reporter Based Analytical Flow Cytometry for miRNA Induced Regulation in Mammalian Cells
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Author:
Date:
2018-09-05
[Abstract] MicroRNA-induced gene regulation is a growing field in basic and translational research. Examining this regulation directly in cells is necessary to validate high-throughput data originated from RNA sequencing technologies. For this several studies employ luciferase-based reporters that usually measure the whole cell population, which comes with low resolution for the complexity of the miRNA-induced regulation. Here, we provide a protocol using a dual-fluorescence reporter and flow cytometry reaching single cell resolution; the protocol contains a simplified workflow that includes: vector generation, data acquisition, processing, and analysis using the R environment. Our protocol enables high-resolution measurements of miRNA induced post-transcriptional gene regulation and combined with ...
[摘要] MicroRNA诱导的基因调控是基础和转化研究中不断增长的领域。 直接在细胞中检查该调节对于验证源自RNA测序技术的高通量数据是必要的。 对于这一研究,一些研究采用基于荧光素酶的报告基因,通常测量全细胞群,其具有低分辨率的miRNA诱导调节的复杂性。 在这里,我们提供使用双荧光报告基因和流式细胞仪达到单细胞分辨率的方案; 该协议包含一个简化的工作流程,包括:使用R环境进行矢量生成,数据采集,处理和分析。 我们的协议可实现miRNA诱导的转录后基因调控的高分辨率测量,并结合系统生物学,可用于估计miRNA的熟练程度。
【背景】MicroRNAs(miRNA)是高度保守的小型非蛋白质编码RNA(21-22nt),可调节转录后基因表达并调节基因生物学过程,如发育和细胞稳态(Lagos-Quintana et al。,2001; Fabian et al。,2010; Bartel,2018),包括miRNA表达与肿瘤进展和侵袭性相关的几种病理(Lu et al。, 2005; Di Leva和Croce,2013; Krishnan et al。,2015; Bertoli et ...
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| Generation of Luciferase-expressing Tumor Cell Lines
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Author:
Date:
2018-04-20
[Abstract] Murine tumor models have been critical to advances in our knowledge of tumor physiology and for the development of effective tumor therapies. Essential to these studies is the ability to both track tumor development and quantify tumor burden in vivo. For this purpose, the introduction of genes that confer tumors with bioluminescent properties has been a critical advance for oncologic studies in rodents. Methods of introducing bioluminescent genes, such as firefly luciferase, by viral transduction has allowed for the production of tumor cell lines that can be followed in vivo longitudinally over long periods of time. Here we describe methods for the production of stable luciferase expressing tumor cell lines by lentiviral transduction.
[摘要] 鼠肿瘤模型对于我们对肿瘤生理学知识和有效肿瘤治疗方法发展的进展至关重要。 这些研究的关键是能够跟踪肿瘤发展并量化体内肿瘤负荷。 为此,引入赋予肿瘤生物发光特性的基因已经成为啮齿动物肿瘤研究的重要进展。 通过病毒转导引入生物发光基因(例如萤火虫萤光素酶)的方法已经允许产生可以在体内纵向长时间地进行的肿瘤细胞系。 在这里我们描述了通过慢病毒转导产生稳定表达荧光素酶的肿瘤细胞系的方法。
【背景】体内跟踪细胞最重要的是能够通过微创方法从外部检测它们。使用来自萤火虫的荧光素酶(Photinus pyralis )的酶促生物发光是用于体内基于图像的细胞追踪的广泛使用的方法。生物发光已被用于各种体内应用,包括报告基因表达的无创成像(Herschman,2004),研究昼夜节律(Southern and Millar,2005),成像脑卒中(Vandeputte
萤火虫荧光素酶氧化物萤光素在分子氧,镁和三磷酸腺苷存在下在560nm产生黄绿色光(Wilson和Hastings,1998; ...
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