Golden Gate cloning or Golden Gate assembly[1]  is a molecular cloning method that allows a researcher to simultaneously and directionally assemble multiple DNA fragments into a single piece using Type IIs restriction enzymes and T4 DNA ligase [2]. This assembly is performed in vitro. Most commonly used Type IIS enzymes include BsaI, BsmBI, and BbsI.

Unlike standard Type II restriction enzymes like EcoRI and BamHI, these enzymes cut DNA outside of their recognition sites and, therefore, can create non-palindromic overhangs[3]. Since 256 potential overhang sequences are possible, multiple fragments of DNA can be assembled by using combinations of overhang sequences[3]. In practice, this means that Golden Gate cloning is typically scarless[3]. Additionally, because the final product does not have a Type II restriction enzyme recognition site, the correctly-ligated product cannot be cut again by the restriction enzyme, meaning the reaction is essentially irreversible[3].

A typical thermal cycler protocol oscillates between 37 °C (optimal for restriction enzymes) and 16 °C (optimal for ligases) many times[4]. While this technique can be used for a single insert, researchers have used Golden Gate cloning to assemble many pieces of DNA simultaneously[5].

Seamless Cloning

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Scar sequences are common in multiple segment DNA assembly[3]. In the multisegment assembly method Gateway, segments are added into the donor with additional att sequences, which overlap in those added segments, and this results in the segments separated by the att sequences[3]. In BioBrick assembly, an eight-nucleotide scar sequence, which codes for a tyrosine and a stop codon, is left between every segment added into the plasmid[3].

Golden Gate assembly uses type II restriction enzymes cutting outside their recognition sequences[3]. Also, the same type II restriction enzyme can generate copious different overhangs on the inserts and the vector, for instance, BsaI creates 256 four-basepair overhangs[3]. If the overhangs are carefully designed, the segments are ligated without scar sequences between them, and the final construct can be quasi-scarless, where the restriction enzyme sites remain on both sides of the insert[3]. As additional segments can be inserted into the vectors without scars within an open reading frame, Golden Gate is widely used in protein engineering[3].

Plasmid Design

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Although Golden Gate Cloning speeds up multisegment cloning, careful design of donor and recipient plasmids is required[5]. In each cloning step, Golden Gate Cloning can assemble up to nine fragments and only requires homology in type II restriction enzyme sites so that the DNA fragments can be ligated seamlessly[5]. After the fragments are ligated, the product will not have the original type IIS restriction site and will not be redigested in ligation reaction afterwards[5]. Meanwhile, the original restriction sites, which are not ligated, can be redigested so that they can add more fragments into the plasmid[5]. If the DNA fragments are well-designed to be compatible to one another, they can be ligated in a linear order in one step[5].

Cloning Standard

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Restriction enzyme DNA assembly has cloning standards to minimize the change in cloning efficiency and the function of the plasmid, which can be caused by compatibility of the restriction sites on the insert and those on the vector[6].

Golden Gate assembly's cloning standards have two tiers. First-tier Golden Gate assembly constructs the single-gene construct by adding in genetic elements such as promoter, open reading frames, and terminators[6].Then, second-tier Golden Gate assembly combine several constructs made in first-tier assembly to make a multigene construct[6]. To achieve second-tier assembly, modular cloning(MoClo) system and GoldenBraid2.0 standard are used[6].

MoClo System

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MoClo utilizes a parallel approach, where all constructs from tier-one(level 0 modules) have restriction sites for BpiI on both sides of the inserts. The vector(also known as "destination vector"), where genes will be added, has an outward-facing BsaI restriction site with a drop-out screening cassette[6]. LacZ is a common screening cassette, where it is replaced by the multigene construct on the destination vector[6]. Each tier-one construct and the vector have different overhangs on them yet complimentary to the overhang of the next segment, and this determines the layout of the final multigene construct[6]. Golden Gate cloning usually starts with level 0 modules[5]. However, if the level 0 module is too large, cloning will start from level -1 fragments, which have to be sequenced, to help cloning the large construct[5]. If starting from level -1 fragments, the level 0 modules do not need to be sequenced again, whereas if staring from level 0 modules, the modules must be sequenced[5].

Level 0 Modules

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Level 0 modules are the base for MoClo system, where they contain genetic elements like a promoter, a 5' untranslated region (UTR), a coding sequence, and a terminator[5]. For the purpose of Golden Gate Cloning, the internal sequences of level 0 modules should not contain type IIS restriction enzymes sites for BsaI, BpiI, and Esp3I while surrounded by two BsaI restriction sites in inverted orientation[5]. Level 0 modules without type IIS restriction sites flanking can add the BsaI sites during the process of Golden Gate cloning[5].

If the level 0 modules contains any unwanted restriction site, they can be mutated in silico by removing one nucleotide from the type IIS restriction site[5]. In this process, one needs to make sure that the introduced mutation will not affect the genetic function encoded by the sequence of interest[5]. A silent mutation in the coding sequence is preferred, for it neither changes the protein sequence nor the function of the gene of interest[5].

Level -1 Fragments
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Level -1 fragments are used to help cloning large level 0 modules[5]. To clone level -1 fragments, blunt-end cloning with restriction ligation can be used[5]. The vector used in cloning level -1 fragments cannot contain type IIS restriction site BpiI that is used for the following assembly step[5]. Moreover, the vector should also have a different selection marker from the destination vector in next assembly step, for example, if spectinomycin resistance is used in level 0 modules, level -1 fragments should have another antibiotic resistance like ampicillin[5].

Level 1 constructs

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The level 1 destination vector determines the position and orientation of each gene in the final construct[7]. There are fourteen available level 1 vectors, which differ only by the sequence of the flanking fusion sites while being identical in the internal fusion sites[7]. Hence, all vectors can assemble the same level 0 parts[7].

As all level 1 vectors are binary plasmids, they are used for Agrobacterium mediated temporary expression in plants[7].

Level 2 constructs

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Level 2 vectors have two inverted BpiI sites from the insertion of level 1 modules[7]. The upstream fusion site is compatible to a gene cloned in level 1 vector while the downstream fusion site has a universal sequence[7]. Each cloning allows 2-6 genes to be inserted in the same vector[7].

Adding more genes in one cloning step is not recommended, for this would result in incorrect constructs[7]. On one hand, this can induce more restriction sites in the construct, where this open construct allows additional genes be added[7]. On the other hand, this can also eliminate restriction sites, where this close construct stop the further addition of genes[7].

Therefore, constructs of more than six genes need successive cloning steps, which requires end-linkers containing BsaI or BsmBI internal restriction sites and blue or purple markers[7]. Each cloning step needs to alternate the restriction site and the marker[7]. Furthermore, two restriction enzymes are needed, where BpiI is used for releasing level 1 modules from level 1 constructs and BsaI/BsmBI is for digesting and opening the recipient level 2-n plasmid[7]. When screening, the correct colonies should alternate from blue to purple every cloning step, but if a "closed" end-linker is used, the colonies will be white[7].

GoldenBraid

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In standard Golden Gate Cloning, the restriction sites from the previous tier construct cannot be reused[8]. To add more genes to the construct, restriction sites of a different type IIS restriction enzyme need to be added to the destination vector[8]. As going up the hierarchy level, this requires an indefinite amount of destination plasmids to be designed[8].

GoldenBraid overcomes the problem of designing numerous destination vectors by having a double loop, which is the "braid," to allow binary assembly of multiple constructs[8]. There are two levels of destination plasmids, level α and level Ω[8]. Each level of plasmids can be used as entry plasmids for the other level of plasmids for multiple times because both levels of plasmids have different type IIS restriction sites that are in inverted orientation[8]. For counterselection, the two levels of plasmids differ in their antibiotic resistance markers[8].

References

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  1. ^ Engler, Carola; Kandzia, Romy; Marillonnet, Sylvestre (2008-11-05). "A One Pot, One Step, Precision Cloning Method with High Throughput Capability". PLOS ONE. 3 (11): e3647. doi:10.1371/journal.pone.0003647. ISSN 1932-6203. PMC 2574415. PMID 18985154.{{cite journal}}: CS1 maint: PMC format (link) CS1 maint: unflagged free DOI (link)
  2. ^ Biolabs, New England. "Golden Gate Assembly | NEB". www.neb.com. Retrieved 2017-04-25.
  3. ^ a b c d e f g h i j k Weber, Ernst; Engler, Carola; Gruetzner, Ramona; Werner, Stefan; Marillonnet, Sylvestre (2011-02-18). "A Modular Cloning System for Standardized Assembly of Multigene Constructs". PLOS ONE. 6 (2): e16765. doi:10.1371/journal.pone.0016765. ISSN 1932-6203. PMC 3041749. PMID 21364738.{{cite journal}}: CS1 maint: PMC format (link) CS1 maint: unflagged free DOI (link)
  4. ^ Engler, Carola; Gruetzner, Ramona; Kandzia, Romy; Marillonnet, Sylvestre (2009-05-14). "Golden Gate Shuffling: A One-Pot DNA Shuffling Method Based on Type IIs Restriction Enzymes". PLOS ONE. 4 (5): e5553. doi:10.1371/journal.pone.0005553. ISSN 1932-6203. PMC 2677662. PMID 19436741.{{cite journal}}: CS1 maint: PMC format (link) CS1 maint: unflagged free DOI (link)
  5. ^ a b c d e f g h i j k l m n o p q r s Engler, Carola; Marillonnet, Sylvestre (2014-01-01). "Golden Gate cloning". Methods in Molecular Biology (Clifton, N.J.). 1116: 119–131. doi:10.1007/978-1-62703-764-8_9. ISSN 1940-6029. PMID 24395361.
  6. ^ a b c d e f g Casini, Arturo; Storch, Marko; Baldwin, Geoffrey S.; Ellis, Tom. "Bricks and blueprints: methods and standards for DNA assembly". Nature Reviews. Molecular Cell Biology. 16 (9): 568–576. doi:10.1038/nrm4014. ISSN 1471-0080. PMID 26081612.
  7. ^ a b c d e f g h i j k l m n Marillonnet, Sylvestre; Werner, Stefan (2015-01-01). "Assembly of Multigene Constructs Using Golden Gate Cloning". Methods in Molecular Biology (Clifton, N.J.). 1321: 269–284. doi:10.1007/978-1-4939-2760-9_19. ISSN 1940-6029. PMID 26082229.
  8. ^ a b c d e f g Sarrion-Perdigones, Alejandro; Falconi, Erica Elvira; Zandalinas, Sara I.; Juárez, Paloma; Fernández-del-Carmen, Asun; Granell, Antonio; Orzaez, Diego (2011-07-07). "GoldenBraid: An Iterative Cloning System for Standardized Assembly of Reusable Genetic Modules". PLOS ONE. 6 (7): e21622. doi:10.1371/journal.pone.0021622. ISSN 1932-6203. PMC 3131274. PMID 21750718.{{cite journal}}: CS1 maint: PMC format (link) CS1 maint: unflagged free DOI (link)