| Polyamine Transport Assay Using Reconstituted Yeast Membranes
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Author:
Date:
2021-01-20
[Abstract] ATP13A2/PARK9 is a late endo-/lysosomal P5B transport ATPase that is associated with several neurodegenerative disorders. We recently characterized ATP13A2 as a lysosomal polyamine exporter, which sheds light on the molecular identity of the unknown mammalian polyamine transport system. Here, we describe step by step a protocol to measure radiolabeled polyamine transport in reconstituted vesicles from yeast cells overexpressing human ATP13A2. This protocol was developed as part of our recent publication (van Veen et al., 2020) and will be useful for characterizing the transport function of ...
[摘要] [摘要] ATP13A2 / PARK9是一种晚期内/溶酶体P5B转运ATPase,与多种神经退行性疾病有关。我们最近将ATP13A2表征为溶酶体多胺出口者,这为未知的哺乳动物多胺转运系统的分子身份提供了线索。在这里,我们逐步描述了从过量表达人ATP13A2的酵母细胞中测量重组囊泡中放射性标记的多胺转运的方案。该方案是我们最新出版物的一部分(van Veen等,2020),将有助于表征其他假定的多胺转运蛋白的转运功能,例如P5B转运ATPase的同工型。
[背景] ATP13A2 / PARK9编码一种普遍表达的晚期内-/溶酶体膜蛋白,与一系列神经退行性疾病有关,例如早发性帕金森氏病(Di Fonzo等,2007 ;Lin等,2008)和Kufor -Rakeb综合征(伴痴呆的早期帕金森病)(Ramirez等,2006 ;Park等,2011)。ATP13A2属于P型转运ATPase ,是一类活性转运蛋白,由于ATP水解而暂时形成磷酸中间产物(Kuhlbrandt ,2004年)。ATP13A2是P5亚家族的成员,该家族已在20多年前通过基因组测序鉴定出来(Axelsen和Palmgren ...
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| Single-step Precision Genome Editing in Yeast Using CRISPR-Cas9
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Author:
Date:
2018-03-20
[Abstract] Genome modification in budding yeast has been extremely successful largely due to its highly efficient homology-directed DNA repair machinery. Several methods for modifying the yeast genome have previously been described, many of them involving at least two-steps: insertion of a selectable marker and substitution of that marker for the intended modification. Here, we describe a CRISPR-Cas9 mediated genome editing protocol for modifying any yeast gene of interest (either essential or nonessential) in a single-step transformation without any selectable marker. In this system, the Cas9 nuclease ...
[摘要] 芽殖酵母中的基因组修饰已经非常成功,主要归功于其高度同源性的DNA修复机制。之前已经描述了几种用于修饰酵母基因组的方法,其中许多方法涉及至少两个步骤:插入选择标记并用该标记取代预期的修饰。在这里,我们描述了CRISPR-Cas9介导的基因组编辑方案,用于在没有任何选择标记的情况下在单步转化中修饰任何感兴趣的酵母基因(基本或非必需)。在该系统中,Cas9核酸酶在选择的基因座处产生双链断裂,这在酵母细胞中通常是致死的,而不管由于无效的非同源末端连接修复导致的靶基因座的重要性。该致死性通过使用源自PCR的修复模板的同源重组导致有效的修复。在涉及必需基因的情况下,用功能性等位基因编辑基因组病变的必要性作为额外的选择层。作为一个激励性的例子,我们描述了使用这种策略替代HEM2,一种必需的酵母基因,以及相应的人类直向同源物ALAD。
【背景】酿酒酵母(Baccharomyces cerevisiae,Baker's酵母)作为一种遗传易处理的生物体具有悠久的历史,并且有许多操作酵母基因组的方法。然而,直到最近,有必要应用选择以分离具有所需遗传改变的克隆(Kearse等人,2012; DiCarlo等人,2013; Lee等人,等,2015; ...
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| Method for Multiplexing CRISPR/Cas9 in Saccharomyces cerevisiae Using Artificial Target DNA Sequences
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Author:
Date:
2017-09-20
[Abstract] Genome manipulation has become more accessible given the advent of the CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats) editing technology. The Cas9 endonuclease binds a single stranded (single guide) RNA (sgRNA) fragment that recruits the complex to a corresponding genomic target sequence where it induces a double stranded break. Eukaryotic repair systems allow for the introduction of exogenous DNA, repair of existing mutations, or deletion of endogenous gene products. Targeting of Cas9 to multiple genomic positions (termed ‘multiplexing’) is achieved by the expression of ...
[摘要] 鉴于CRISPR(集群定期间隔短回归重复)编辑技术的出现,基因组操纵变得更加易于使用。 Cas9核酸内切酶将募集复合物的单链(单向导)RNA(sgRNA)片段结合到相应的基因组靶序列,引发双链断裂。真核修复系统允许引入外源DNA,修复现有突变或内源基因产物的缺失。通过在同一核内表达多个sgRNA来实现Cas9对多个基因组位置的定位(称为“多重”)。然而,CRISPR领域的持续关注是将Cas9意外地定位到基因组内的替代(“脱靶”)DNA位置。我们将安装的人造Cas9靶序列的使用(称为人造基因座上的Cas9复制)描述为允许(i)与单个sgRNA复用的酵母基因组中的用途; (ii)减少/消除可能的脱靶效应,以及(iii)精确控制预定目标序列的放置。
【背景】CRISPR(集群定期间隔回归重复)机制已经在原核生物中演变为具有很高精度编辑任何基因组的能力的原始适应性免疫系统(Jinek等,2012; Sorek等,2013)。这种生物技术需要使用来自化脓性链球菌(或othologous物种)的内切核酸酶(Cas9),单个RNA'引导'序列和外源供体DNA(如果需要)。仅在短短几年内,CRISPR / ...
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