{"title":"Use of a Golden Gate plasmid set enabling scarless MoClo-compatible transcription unit assembly","authors":"Stijn T. de Vries, Laura Kley, Daniel Schindler","doi":"arxiv-2402.03410","DOIUrl":null,"url":null,"abstract":"Golden Gate cloning has become a powerful and widely used DNA assembly\nmethod. Its modular nature and the reusability of standardized parts allow\nrapid construction of transcription units and multi-gene constructs.\nImportantly, its modular structure makes it compatible with laboratory\nautomation, allowing for systematic and highly complex DNA assembly. Golden\nGate cloning relies on Type IIS enzymes that cleave an adjacent undefined\nsequence motif at a defined distance from the directed enzyme recognition\nmotif. This feature has been used to define hierarchical Golden Gate assembly\nstandards with defined overhangs (\"fusion sites\") for defined part libraries.\nThe simplest Golden Gate standard would consist of three part libraries, namely\npromoter, coding and terminator sequences, respectively. Each library would\nhave defined fusion sites, allowing a hierarchical Golden Gate assembly to\ngenerate transcription units. Typically, Type IIS enzymes are used, which\ngenerate four nucleotide overhangs. This results in small scar sequences in\nhierarchical DNA assemblies, which can affect the functionality of\ntranscription units. However, there are enzymes that generate three nucleotide\noverhangs, such as SapI. Here we provide a step-by-step protocol on how to use\nSapI to assemble transcription units using the start and stop codon for\nscarless transcription unit assembly. The protocol also provides guidance on\nhow to perform multi-gene Golden Gate assemblies with the resulting\ntranscription units using the Modular Cloning standard. The transcription units\nexpressing fluorophores are used as an example.","PeriodicalId":501219,"journal":{"name":"arXiv - QuanBio - Other Quantitative Biology","volume":"102 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-02-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - QuanBio - Other Quantitative Biology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2402.03410","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Golden Gate cloning has become a powerful and widely used DNA assembly
method. Its modular nature and the reusability of standardized parts allow
rapid construction of transcription units and multi-gene constructs.
Importantly, its modular structure makes it compatible with laboratory
automation, allowing for systematic and highly complex DNA assembly. Golden
Gate cloning relies on Type IIS enzymes that cleave an adjacent undefined
sequence motif at a defined distance from the directed enzyme recognition
motif. This feature has been used to define hierarchical Golden Gate assembly
standards with defined overhangs ("fusion sites") for defined part libraries.
The simplest Golden Gate standard would consist of three part libraries, namely
promoter, coding and terminator sequences, respectively. Each library would
have defined fusion sites, allowing a hierarchical Golden Gate assembly to
generate transcription units. Typically, Type IIS enzymes are used, which
generate four nucleotide overhangs. This results in small scar sequences in
hierarchical DNA assemblies, which can affect the functionality of
transcription units. However, there are enzymes that generate three nucleotide
overhangs, such as SapI. Here we provide a step-by-step protocol on how to use
SapI to assemble transcription units using the start and stop codon for
scarless transcription unit assembly. The protocol also provides guidance on
how to perform multi-gene Golden Gate assemblies with the resulting
transcription units using the Modular Cloning standard. The transcription units
expressing fluorophores are used as an example.
金门克隆已成为一种功能强大、应用广泛的 DNA 组装方法。重要的是,它的模块化结构使其与实验室自动化兼容,可以进行系统化和高度复杂的 DNA 组装。GoldenGate 克隆依靠的是 IIS 型酶,这种酶可以在与定向酶识别基元之间的确定距离上裂解相邻的未定义序列基元。最简单的金门标准由三个部分库组成,分别是启动子序列、编码序列和终止子序列。最简单的金门标准由三个部分库组成,分别是启动子序列、编码序列和终止子序列。每个部分库都有确定的融合位点,允许分级金门组装以生成转录单元。通常使用 IIS 型酶,它能产生四个核苷酸的悬垂。这会导致分层 DNA 组装中出现小的疤痕序列,从而影响转录单元的功能。不过,也有一些酶能产生三个核苷酸的悬垂,如 SapI。在此,我们提供了一个分步方案,说明如何使用 SapI 利用起始密码子和终止密码子组装转录单位,以实现无痕转录单位组装。该方案还提供了如何使用模块化克隆标准对得到的转录单位进行多基因金门组装的指导。以表达荧光团的转录单位为例。