The ability to rapidly design, build, and test prototypes is of key importance to every engineering discipline. DNA assembly often serves as a rate limiting step of the prototyping cycle for synthetic biology. Recently developed DNA assembly methods such as isothermal assembly and type IIS restriction enzyme systems take different approaches to accelerate DNA construction. We introduce a hybrid method, Golden Gate-Gibson (3G), that takes advantage of modular part libraries introduced by type IIS restriction enzyme systems and isothermal assembly’s ability to build large DNA constructs in single pot reactions. Our method is highly efficient and rapid, facilitating construction of entire multigene circuits in a single day. Additionally, 3G allows generation of variant libraries enabling efficient screening of different possible circuit constructions. We characterize the efficiency and accuracy of 3G assembly for various construct sizes, and demonstrate 3G by characterizing variants of an inducible cell-lysis circuit

Halleran, Andrew D.

Murray, Richard M.

Swaminathan, Anandh

Caltech Authors - Main

 1 
Single day construction of multi-gene circuits with 3G assembly 
Andrew D. Halleran1, Anandh Swaminathan2, and Richard M. Murray1, 2 
1.   Bioengineering, California Institute of Technology, Pasadena, CA.  
2.   Control and Dynamical Systems, California Institute of Technology, Pasadena, 
CA.  
 
 
 
 
 
 
 
 
 
 
 
Supplementary Information 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 2 
Detailed protocol for 3G assembly:  
 
The 3G assembly protocol can be broken into two sections. The first is a set of one-
time preparations that result in a library of UNS adapters, primers to amplify from those 
adapters, and vectors with UNS1-UNS10 flanking sequences for Gibson assembly. 
The second is the daily pipeline that is performed to assemble multi-gene circuits.  
 
Initial preparations:  
Design of UNS adapter sequences 
The first step in the 3G assembly pipeline is the design of UNS adapter sequences. For 
most Golden Gate systems geared towards use in synthetic biology, there are four 
standard part types (Promoters, 5’ UTRs, CDSs, and Terminators), each with a unique 
overhang sequence that distinguishes them. In the CIDAR MoClo system, which we 
use in this paper, promoters are distinguished as ‘AB’ fragments (they have a 4bp ‘A’ 
overhang on the left, and a 4bp ‘B’ overhang on the right), 5’ UTRs as ‘BC’ fragments, 
CDSs as ‘CD’ and terminators as ‘DE.’1 Thus, a standard transcriptional unit assembly, 
in the absence of a backbone, results in an ‘A’ overhang on the left and an ‘E’ 
overhang on the right. In the CIDAR MoClo system, vectors that are designed to 
receive transcriptional units can be cut with BsaI to reveal ‘A’ and ‘E’ compatible 
overhangs on the vector which then ligate to the insert transcriptional units.  
 
Our goal is to design adapter sequences that contain either a BsaI cutsite that reveals 
the binding site for the ‘A’ overhang on the promoter, or the binding site for the ‘E’ 
overhang on the terminator, and a landing pad that can be used for priming in PCR and 
as regions of homology in Gibson assembly. We use the unique nucleotide sequences 
(UNSs) designed by Torella et al. as our landing pads for our 3G assembly method.2 
Below are example designs of a UNS1_A adapter and a UNS10_E adapter.  
 
 
Figure 1: UNS1_A adapter 
 
 
Figure 2: UNS10_E adapter.  
 
 
 3 
These designs are specific to the library developed by Iverson et al.1 For application to 
other type IIS systems, the sticky end and / or the restriction enzyme used to reveal it 
will change. However, the entire 40bp UNS sequence will stay the same.  
 
To maximize flexibility, all vectors are flanked by UNS1 and UNS10. Therefore, for 
every multi-gene assembly the first fragment must have UNS1 on the left and the last 
fragment must have UNS10 on the right. For example, a one transcriptional unit 
assembly should look like: 
 
Fragment 1 = UNS1_A – Promoter – UTR – CDS – Terminator – UNS10_E 
 
 
Multi-transcriptional unit assembly should again have UNS1 on the left of the first 
fragment and UNS10 on the right of the last fragment, but fragments that are adjacent 
should share a UNS sequence. For example, in a three transcriptional unit assembly 
 
Fragment 1 = UNS1_A – P1 – UTR1 – CDS1- Terminator1 – UNS2_E 
Fragment 2 = UNS2_A – P2 – UTR2 – CDS2 – Terminator2 – UNS3_E 
Fragment 3 = UNS3_A – P3 – UTR3 – CDS3 – Terminator3 – UNS10_E 
 
This will result in a final product of: 
  
U1-Transcriptional Unit 1 – U2 – Transcriptional Unit 2 – U3 – Transcriptional Unit 3 – U10 
 
that will then be assembled into a U1-U10 backbone.  
 
To take full advantage of the UNS1 / UNS10 sequences the following adapters must be 
generated: 
1.   UNS1_A 
2.   UNS2_A 
3.   UNS2_E 
4.   UNS3_A 
5.   UNS3_E 
6.   UNS4_A 
7.   UNS4_E 
8.   UNS5_A 
9.   UNS5_E 
10.  UNS6_A 
11.  UNS6_E 
12.  UNS7_A 
13.  UNS7_E 
14.  UNS8_A 
15.  UNS8_E 
16.  UNS9_A 
17.  UNS9_E 
 4 
18.  UNS10_E 
 
This list is reduced by our choice not to use UNS2 in our assemblies. We found that 
UNS2 and UNS5 would occasionally join together in the final Gibson assembly, so we 
removed UNS2 from our set of adapters. This leaves:  
 
1.   UNS1_A 
2.   UNS3_A 
3.   UNS3_E 
4.   UNS4_A 
5.   UNS4_E 
6.   UNS5_A 
7.   UNS5_E 
8.   UNS6_A 
9.   UNS6_E 
10.  UNS7_A 
11.  UNS7_E 
12.  UNS8_A 
13.  UNS8_E 
14.  UNS9_A 
15.  UNS9_E 
16.  UNS10_E 
 
By designing these adapters, up to eight transcriptional units can be combined in a 
single day. For even more, custom generation of additional orthogonal UNSs can be 
performed using publicly available tools.3  
 
Each of these adapters is 53bp in total length. We found that the most cost-effective 
and efficient way to synthesize these sequences was to split each adapter into a top 
and bottom strand and order them as oligos that we then annealed. All sequences 
used can be found in Supplementary Table 1.  
 
Annealing UNS adapter oligos:  
After receiving single stranded oligos we then anneal them to generate double 
stranded DNA that can be cut by our type IIS restriction enzyme of choice. We follow 
IDT’s recommended protocol for annealing oligos 
(https://www.idtdna.com/pages/education/decoded/article/annealing-
oligonucleotides).  
 
In brief, we combine the oligos at 5μM in Duplex Buffer (100 mM Potassium Acetate; 
30 mM HEPES, pH 7.5). We then heat the mix in a thermal cycler to 94°C for 2 minutes 
and cool by 1°C every minute. We then dilute the reaction from 5μM to 50nM in 1x TE 
or nuclease free water. The annealed adapters can now be stored at -20°C until they 
are needed.   
 
 5 
 
Designing UNS primers:  
Based on the UNS adapters we designed above, we also need the following primers:  
1.   UNS1_Forward 
2.   UNS3_Forward 
3.   UNS4_Forward 
4.   UNS5_Forward 
5.   UNS6_Forward 
6.   UNS7_Forward 
7.   UNS8_Forward 
8.   UNS9_Forward 
9.   UNS3_Reverse 
10.  UNS4_Reverse 
11.  UNS5_Reverse 
12.  UNS6_Reverse 
13.  UNS7_Reverse 
14.  UNS8_Reverse 
15.  UNS9_Reverse 
16.  UNS10_Reverse 
 
All primer sequences were designed for a 64°C annealing temperature using NEB’s 
melting temperature calculator for Q5 (https://tmcalculator.neb.com/#!/main). All primer 
sequences can be found in Supplementary Table 1.  
 
Preparation of UNS1-UNS10 backbones:  
The final preparation is to generate destination vectors that are linear and flanked by 
the UNS1 and UNS10 sequences on either side. This is easily done by PCRing an 
existing backbone to linearize it, including overhangs on the primer sequences to add 
UNS1 on one side of the vector and UNS10 on the other. Before using the UNS1-
UNS10 backbones in a Gibson reaction we recommend gel extracting the PCR 
product to increase efficiency.  
 
Daily pipeline: 
Golden Gate assembly:  
The first step in the daily pipeline is to assemble the individual transcriptional units of 
interest, each in their own reaction tube, and add on the adapters we designed above.  
 
As an example, we will design a two transcriptional unit assembly, that will result in the 
U1 – Transcriptional Unit 1 – U3 – Transcriptional Unit 2 – U10 in our vector backbone.  
  
Reaction 1: 
0.5μL UNS1_A (50nM stock) 
0.5μL UNS3_E (50nM stock) 
0.5μL Promoter 1 (30nM stock) 
0.5μL UTR 1 (30nM stock) 
 6 
0.5μL CDS 1 (30nM stock) 
0.5μL Terminator 1 (30nM stock) 
0.5μL 10x T4 DNA Ligase Buffer  
0.25μL T4 DNA Ligase  
0.25μL BsaI 
1.0μL nuclease free water 
 
Reaction 2: 
0.5μL UNS3_A (50nM stock) 
0.5μL UNS10_E (50nM stock) 
0.5μL Promoter 2 (30nM stock) 
0.5μL UTR 2 (30nM stock) 
0.5μL CDS 2 (30nM stock) 
0.5μL Terminator 2 (30nM stock) 
0.5μL 10x T4 DNA Ligase Buffer  
0.25μL T4 DNA Ligase  
0.25μL BsaI 
1.0μL nuclease free water 
 
Golden Gate conditions: 
{37°C for 3 minutes 
16°C for 4 minutes} 
 (9 cycles) 
50°C for 5 minutes 
4°C hold 
 
Post Golden Gate Amplification:  
We now have our individual transcriptional units assembled, and a standard type IIS 
cloning system would transform our reaction into cells to amplify the product.1 Instead, 
in 3G we use the UNS adapters added to each construct to amplify the transcriptional 
units directly from the Golden Gate reaction. Not only does this have the advantage of 
saving the time to transform, pick colonies, and miniprep plasmid, PCR keeps any 
variants included in the Golden Gate reaction (multiple different promoters or UTRs for 
example), thus allowing the downstream Gibson reaction to generate circuit variants in 
a single pot.  
 
PCR conditions:  
25uL 2x Q5 Hot Start Master Mix 
2.5uL 10μM Forward primer 
2.5uL 10μM Reverse primer  
18.5μL nuclease free water 
1.5μL Golden Gate product  
 
 
 7 
Cycling conditions:  
98°C for 30 seconds 
 
{98°C for 15 seconds 
64°C for 30 seconds 
72°C for 30 seconds per kb} 
(27 cycles) 
 
72°C for 5 minutes 
4°C hold  
 
PCR purification:  
PCR products were purified using the QIAquick Gel Extraction kit and eluted in 15μL of 
elution buffer (Qiagen). We found that gel extraction increases the efficiency of the 
downstream Gibson reaction.  
 
Gibson assembly:  
Gibson assembly was performed using NEBuilder HiFi DNA Assembly Master Mix. All 
fragments, included vector backbone, were combined at 2nM final concentration in a 
5μL reaction and incubated at 50°C for 1 hour. 
 
Transformation:  
Transformations were performed using 2μL of the Gibson assembly reaction 
transformed into 50μL of chemically competent DH5α cells (NEB 5-alpha Competent E. 
coli (High Efficiency)). Cells were outgrown at 37°C in 300μL of SOC, 100 μL of which 
was plated on LB-Agar and grown overnight at 37°C.  
 
 
References: 
1. Iverson, S. V., Haddock, T. L., Beal, J., and Densmore, D. M. (2015) CIDAR MoClo: 
improved MoClo assembly standard and new E. coli part library enable rapid 
combinatorial design for synthetic and traditional biology, ACS Synthetic Biology 5, 99-
103. 
2. Torella, J. P., Boehm, C. R., Lienert, F., Chen, J.-H., Way, J. C., and Silver, P. A. 
(2013) Rapid construction of insulated genetic circuits via synthetic sequence-guided 
isothermal assembly, Nucleic Acids Research 42, 681-689. 
3. Casini, A., MacDonald, J. T., Jonghe, J. D., Christodoulou, G., Freemont, P. S., 
Baldwin, G. S., and Ellis, T. (2013) One-pot DNA construction for synthetic biology: the 
Modular Overlap-Directed Assembly with Linkers (MODAL) strategy, Nucleic Acids 
Research 42, e7-e7. 
 
 
 
 
 8 
Sequences required for 3G assembly: 
To perform 3G assembly using the existing CIDAR MoClo library, UNS adapters 
corresponding to both A and E overhangs are required. In addition, primer sequences 
complementary to the UNS adapters are required to amplify the Golden Gate reactions 
must also be ordered. The table below lists all sequences designed and used for 3G 
assembly. All primers were ordered without modification and in the smallest scale 
reaction from Integrated DNA Technologies.  
 
Table 1:  
 
Primer 
description 
Sequence 
UNS1_A Top CATTACTCGCATCCATTCTCAGGCTGTCTCGTCTCGTCTCGGA
GAGAGACCGG 
UNS1_A Bottom CCGGTCTCTCTCCGAGACGAGACGAGACAGCCTGAGAATGGA
TGCGAGTAATG 
UNS3_A Top GCACTGAAGGTCCTCAATCGCACTGGAAACATCAAGGTCGGGA
GAGAGACCGG 
UNS3_A Bottom CCGGTCTCTCTCCCGACCTTGATGTTTCCAGTGCGATTGAGGA
CCTTCAGTGC 
UNS3_E Top GGGGTCTCTGCTTGCACTGAAGGTCCTCAATCGCACTGGAAAC
ATCAAGGTCG 
UNS3_E Bottom CGACCTTGATGTTTCCAGTGCGATTGAGGACCTTCAGTGCAAG
CAGAGACCCC 
UNS4_A Top  CTGACCTCCTGCCAGCAATAGTAAGACAACACGCAAAGTCGGA
GAGAGACCGG 
UNS4_A Bottom CCGGTCTCTCTCCGACTTTGCGTGTTGTCTTACTATTGCTGGCA
GGAGGTCAG 
UNS4_E Top GGGGTCTCTGCTTCTGACCTCCTGCCAGCAATAGTAAGACAAC
ACGCAAAGTC 
UNS4_E Bottom  GACTTTGCGTGTTGTCTTACTATTGCTGGCAGGAGGTCAGAAG
CAGAGACCCC 
UNS5_A Top GAGCCAACTCCCTTTACAACCTCACTCAAGTCCGTTAGAGGGA
GAGAGACCGG 
UNS5_A Bottom CCGGTCTCTCTCCCTCTAACGGACTTGAGTGAGGTTGTAAAGG
GAGTTGGCTC 
UNS5_E Top GGGGTCTCTGCTTGAGCCAACTCCCTTTACAACCTCACTCAAG
TCCGTTAGAG 
UNS5_E Bottom CTCTAACGGACTTGAGTGAGGTTGTAAAGGGAGTTGGCTCAAG
CAGAGACCCC 
UNS6_A Top CTCGTTCGCTGCCACCTAAGAATACTCTACGGTCACATACGGA
GAGAGACCGG 
UNS6_A Bottom CCGGTCTCTCTCCGTATGTGACCGTAGAGTATTCTTAGGTGGC
AGCGAACGAG 
 9 
UNS6_E Top GGGGTCTCTGCTTCTCGTTCGCTGCCACCTAAGAATACTCTAC
GGTCACATAC 
UNS6_E Bottom GTATGTGACCGTAGAGTATTCTTAGGTGGCAGCGAACGAGAAG
CAGAGACCCC 
UNS7_A Top CAAGACGCTGGCTCTGACATTTCCGCTACTGAACTACTCGGGA
GAGAGACCGG 
UNS7_A Bottom CCGGTCTCTCTCCCGAGTAGTTCAGTAGCGGAAATGTCAGAGC
CAGCGTCTTG 
UNS7_E Top GGGGTCTCTGCTTCAAGACGCTGGCTCTGACATTTCCGCTACT
GAACTACTCG 
UNS7_E Bottom CGAGTAGTTCAGTAGCGGAAATGTCAGAGCCAGCGTCTTGAAG
CAGAGACCCC 
UNS8_A Top CCTCGTCTCAACCAAAGCAATCAACCCATCAACCACCTGGGGA
GAGAGACCGG 
UNS8_A Bottom CCGGTCTCTCTCCCCAGGTGGTTGATGGGTTGATTGCTTTGGT
TGAGACGAGG 
UNS8_E Top GGGGTCTCTGCTTCCTCGTCTCAACCAAAGCAATCAACCCATC
AACCACCTGG 
UNS8_E Bottom CCAGGTGGTTGATGGGTTGATTGCTTTGGTTGAGACGAGGAAG
CAGAGACCCC 
UNS9_A Top GTTCCTTATCATCTGGCGAATCGGACCCACAAGAGCACTGGGA
GAGAGACCGG 
UNS9_A Bottom CCGGTCTCTCTCCCAGTGCTCTTGTGGGTCCGATTCGCCAGAT
GATAAGGAAC 
UNS9_E Top GGGGTCTCTGCTTGTTCCTTATCATCTGGCGAATCGGACCCAC
AAGAGCACTG 
UNS9_E Bottom CAGTGCTCTTGTGGGTCCGATTCGCCAGATGATAAGGAACAAG
CAGAGACCCC 
UNS10_E Top GGGGTCTCTGCTTCCAGGATACATAGATTACCACAACTCCGAG
CCCTTCCACC 
UNS10_E 
Bottom 
GGTGGAAGGGCTCGGAGTTGTGGTAATCTATGTATCCTGGAAG
CAGAGACCCC 
UNS1_Forward CATTACTCGCATCCATTCTCAGGC 
UNS3_Forward GCACTGAAGGTCCTCAATCG 
UNS4_Forward CTGACCTCCTGCCAGCAATAGT 
UNS5_Forward GAGCCAACTCCCTTTACAACCT 
UNS6_Forward CTCGTTCGCTGCCACCTAAGAA 
UNS7_Forward CAAGACGCTGGCTCTGACATTT 
UNS8_Forward CCTCGTCTCAACCAAAGCAATC 
UNS9_Forward GTTCCTTATCATCTGGCGAATCGGA 
UNS3_Reverse CGACCTTGATGTTTCCAGTGCG 
UNS4_Reverse GACTTTGCGTGTTGTCTTACTAT 
 10 
UNS5_Reverse CTCTAACGGACTTGAGTGAGGTTG 
UNS6_Reverse GTATGTGACCGTAGAGTATTCTTAGGTGG 
UNS7_Reverse CGAGTAGTTCAGTAGCGGAAA 
UNS8_Reverse CCAGGTGGTTGATGGGTTGATT 
UNS9_Reverse CAGTGCTCTTGTGGGTCCGAT 
UNS10_Reverse GGTGGAAGGGCTCGGAGTTG 
  
All adapters were annealed following the protocol defined by IDT: 
https://www.idtdna.com/pages/education/decoded/article/annealing-oligonucleotides 
 
 
 
 
 
 
 
 
 
 
In figure 2 we tested variants of an inducible cell lysis circuit. The pools of the different 
promoters and 5’ UTRs we used are provided below along with references to the 
original papers from which they were taken.  
 
Table 2:  
 
Promoters 
used for 
LasR 
Sequence 
J231061 TTTACGGCTAGCTCAGTCCTAGGTATAGTGCTAGC 
J231161 TTGACAGCTAGCTCAGTCCTAGGGACTATGCTAGC 
J231191 TTGACAGCTAGCTCAGTCCTAGGTATAATGCTAGC 
P112 TTGACAATTAATCATCCGGCTCTTAGTGTTTGTGGA 
P132 TTCCCTATTAATCATCCGGCTCGTATAATGTGTGGA 
5' UTRs 
used for 
LasR 
Sequence 
BCD22 GGGCCCAAGTTCACTTAAAAAGGAGATCAACAATGAAAGCAATTTT
CGTACTGAAACATCTTAATCATGCTAAGGAGGTTTTCT 
BCD122 GGGCCCAAGTTCACTTAAAAAGGAGATCAACAATGAAAGCAATTTT
CGTACTGAAACATCTTAATCATGCTGCGGAGGGTTTCT 
BCD82 GGGCCCAAGTTCACTTAAAAAGGAGATCAACAATGAAAGCAATTTT
CGTACTGAAACATCTTAATCATGCATCGGACCGTTTCT 
 11 
5' UTRs 
used for 
ΦX174E 
Sequence  
Bujard RBS3 GAATTCATTAAAGAGGAGAAAGGTACC 
Collins RBS4 CAGGACGCACTGACCGAATTCGCATTAAGGAGGTACA 
UTR15 AATAATTTTGTTTAACTTTAAGAAGGAGATATA 
BCD22 GGGCCCAAGTTCACTTAAAAAGGAGATCAACAATGAAAGCAATTTT
CGTACTGAAACATCTTAATCATGCTAAGGAGGTTTTCT 
BCD122 GGGCCCAAGTTCACTTAAAAAGGAGATCAACAATGAAAGCAATTTT
CGTACTGAAACATCTTAATCATGCTGCGGAGGGTTTCT 
BCD82 GGGCCCAAGTTCACTTAAAAAGGAGATCAACAATGAAAGCAATTTT
CGTACTGAAACATCTTAATCATGCATCGGACCGTTTCT 
 
1.   Anderson Promoter Library: http://parts.igem.org/Promoters/Catalog/Anderson 
2.    Mutalik, V. K., Guimaraes, J. C., Cambray, G., Lam, C., Christoffersen, M. J., 
Mai, Q.-A., Tran, A. B., Paull, M., Keasling, J. D., and Arkin, A. P. (2013) Precise 
and reliable gene expression via standard transcription and translation initiation 
elements, Nature Methods 10, 354. 
3.   Lutz, R., and Bujard, H. (1997) Independent and tight regulation of 
transcriptional units in Escherichia coli via the LacR/O, the TetR/O and AraC/I1-
I2 regulatory elements, Nucleic Acids Research 25, 1203-1210. 
4.   Cameron, D. E., and Collins, J. J. (2014) Tunable protein degradation in bacteria, 
Nature Biotechnology 32, 1276. 
5.   Shin, J., and Noireaux, V. (2010) Efficient cell-free expression with the 
endogenous E. coli RNA polymerase and sigma factor 70, Journal of Biological 
Engineering 4, 8.  


Single Day Construction of Multigene Circuits with 3G Assembly

https://authors.library.caltech.edu/85692/5/sb8b00060_si_001.pdf

Single Day Construction of Multigene Circuits with 3G Assembly

Abstract

Similar works

Full text

Available Versions

Caltech Authors - Main