CH391L/S14/MAGE

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MAGE

Mulitplex Automated Genome Engineering

MAGE, or multiplex automated genome engineering, is a technique developed in George Church's lab at Harvard that can be used for large-scale programming and evolution of cells. Many directed evolution and in vitro technologies are limited to manipulations of single genes, making it slow if trying to alter multiple loci. MAGE has advantages over these techniques because it is able to simultaneously target many loci in parallel for modification.[1] Modification can be in the form of mismatch mutations, insertions, or deletions. Through the use of oligos with well-defined sequences, predictable modification can arise. However, through degenerate nucleotides, high-diversity chromosome modifications occur, producing a large variety of genetic variants.
File:Lycopene Production.jpg
MAGE schematic and lycopene production pathway.l[2]

Lamba-Red Bacteriophage

Modification in MAGE is done through oligo-mediated allelic replacement, which is controlled by the λ-Red single-stranded DNA binding protein β. This protein works by binding the single-stranded oligo and helping it to displace the Okazaki fragment on the lagging strand. Normally, the cell's repair proteins would spot the mismatch, but one of the key genes for the repair mechanism has been knocked out in the strain used, EcNR2. Upon the next round of DNA replication, the introduced oligo is copied and becomes part of genome. It is also possible that the fragments can be replaced by other near matching oligos in succeeding rounds, generating even more diversity. The Church group found using 90-mer oligos were the most efficient for replacement. This is due to the λ-Red protein needing at least 30 bps to complex DNA, and that 90bp presents a good chance of homology to the target, while oligos larger than 90-mer have a higher chance of forming secondary structure, greatly reducing replacement effieciency.

File:Figurer 2.jpg
Efficiency of allelic replacement (a) mismatch, (b) insertion, (c) deletion.l[1]

Efficiency of MAGE

Through oligo-mediated allelic replacement with the λ-Red single-stranded DNA binding protein β, mismatch mutations up to 30bp, insertions up to 30bp, and deletions of up to 45 kbp were introduced to cell populations.[1] The efficiency of a mismatch or insertion is based on its homology to the genome target, and deletion efficiency is based on size. Since oligos with more homology to target sites are incorporated at a higher frequency, MAGE can be tuned to provide desired evolution. Efficiency can be up to as high as 35% per cycle, but decreases greatly with increase in replacement size. On average, an 18 bp oligo has a 2-5% replacement frequency per cycle. [3]

Automation

File:MAGE Cycles.jpg
Increased divergence from wild-type lacZ.[1]

Measuring Sequence Diversity Rate

Finding the rate of genomic diversification by MAGE was done by making mismatch changes using three different 90-mer oligos to target a part of the lacZ gene. Oligos cN6 and cN30 contained 6 and 30 sequential degenerate bases, respectively. While, iN6 oligos had 6 degenerate bases spread out over a 30 bp region. [1] The data comes from 96 random clonal isolates after MAGE cycles of 2, 5, 10, or 15, which gives a good idea of variation in the cell populations. In the cN6 population, more than 4.3 billion variants were produced each day. After 15 cycles, all genotype combinations of N6 cell populations were created from either the cN6 or iN6. While only 21.8% of the cN30 population had accomplished allelic replacement in 15 cycles, because it is much more difficult to replace 30 consecutive degenerate bases. The Church group determined that MAGE diversity is dependent on: "the degree of sequence variation desired at each locus, the number of loci targeted, and the number of MAGE cycles performed".[1]

Lycopene Production

Lycopene is a carotenoid pigment found in tomatoes and other red fruits and vegetables, because it is non-toxic and has antioxidant properties it is a good food coloring agent. It is also an important intermediate in the synthesis of many other carotenoids. Screening lycopene production is simple because colonies producing it show intense red pigmentation.

DXP Pathway

File:Mage Results.jpg
(a) Gene targets, (b) Growth of strains, (c) DXP pathway genes[1]

Exhibiting that MAGE can be used to target specific sequences with well-defined oligos, the 1-deoxy-D-xylulose-5-phosphate or DXP synthesis pathway responsible for lycopene production was targeted. The strain EcHW2 was used with plasmid pAC-LYC which contains essential genes for the final steps of lycopene production. To increase lycopene production, Wang et al. sought to modify 20 genes known to increase lycopene yield as well as 4 secondary genes responsible for decreasing yield. For the lycopene increasing genes, 90-mer oligos with degenerate RBS (DDRRRRRDDDD, D=A,G,T; R=A,G) [1] sequences with some homologous regions on the sides, were used for genes increasing lycopene production. Because the replaced RBS sites were programmed to be similar to the Shine-Dalgarno sequence (TAAGGAGGT), translation efficiency increased. For the remaining four genes, two nonsense mutations were inserted into the open reading frame via oligos, inactivating these genes and increasing lycopene yield. Screening ~10^5 colonies after 5-35 MAGE cycles resulted in cell populations increasing lycopene production five fold relative to the ancestral strain. Sequencing variants showed that RBS convergence toward the consensus Shine-Dalgarno sequence.

Specificity of MAGE

Through the lycopene production pathway, the Church group showed that MAGE could be extremely specific if well-defined oligos are introduced. From the DXP pathway, translation optimization of lycopene production genes such as idi alone (EcHW2a) increased lycopene production 40%, while optimizing dxs and idi increased production by 390% (ExHW2e). [1] It was also shown that in the secondary pathway, inactivation of gdhA increases lycopene production but lowers growth rate in EcHW2b by 32%. The specificity possible by MAGE use was expanded by the Church group to other projects.

CAGE

Hierarchical Conjugative Assembly (CAGE) was developed in George Church's lab as a means to merge sets of codon modifications from MAGE into genomes (each 1/4 size of E. coli genome) with 80 precise codon modifications. It was demonstrated that synonymous codon changes can be combined into strains without lethal effects on the cell population. E. coli has three stop codons and two release factors. Release factor 1 (RF1) recognizes UAA and UAG, while RF2 recognizes UAA and UGA. The hypothesis was that replacing all TAG codons with TAA codons, the genetic dependence on RF1 would be abolished and the newly introduced TAA codons would be recognized by RF2. The group sought to test if E. coli that had replaced all 314 TAG stop codons with TAA codons would be viable. (MG1655 genome) [4]

Codon Modification Strategy

File:CAGE Method.jpg
Strategy for splitting up genome and combining codon modifications.[5]

The genome of MG1655 (a mismatch repair-deficient strain) with 314 TAG stop codons (at least 43 essential genes and 39 TAG codon overlaps of ORF of other genes) was split up into 32 regions, 31 of which had 10 TAG stop codons and one with four. This strategy was selected because pools of at least 10 oligos have been shown to have high replacement efficiency and that the total number of cell divisons to achieve replacement. MAGE was used to introduce all 10 TAG=>TAA codon modifications. The 314 oligos encoding these specific mutations were designed computationally on the basis of previous MAGE experiments. After 18 cycles of MAGE allelic replacement frequencies were analyzed in 1504 clones (47 clones for each 32 segments). The average replacement frequency was 37 +/- 19% after 18 cycles, with 42% of the population unconverted. Of the remaning population, replacements from 1-10 alleles were observed. It was apparent two types of cells were shown to have been evolving: one that ready permits replacement and one largely resistant. It was also shown that no TAG stop codons were essential for survival or robust growth.[4]

Assembling Stop Codon Modifications

Through the use of Hierarchical Conjugative Assembly (CAGE), merging the modifications from MAGE was accomplished. This technique is dependent upon bacterial conjugation to transfer the modified segments. The oriT sequence typically used for conjugation is fused with kanR for integration into E. coli genome by the λ-Red mediated dsDNA recombination. This makes for precise control of conjugation initiation location and use of a ~2-kb casette in place of the 30-kb Hfr fragment(conjugation factors are maintained on recipients as well). [4]
File:Figure 4a.jpg
The site specific conjugation of donor and plasmid. [5]
The 32 strains were converted to 16 pairs for conjugation, with a donor strain transferring its genomic region to a recipient. Selectable markers control placement of transfered DNA, in the donor strain the recoded region was flanked upstream by the oriT-Kan cassete and downstream by a positive selectable marker (ie: antibiotic resistance). The recipient strain contained a different positive selectable marker and a positive-negative selectable marker (tolC), about the recoded region. Through the use of multiplex allele-specific colony PCR (MASC-PCR) 81 integration sites were tested, 12 gave no recombination, 23 sites had a recombination frequency of ~10^-7, 38 sites with ~10^-6, and 8 sites with ~10^-5 recombination frequencies.

The "Amberless" E. coli

The original 32 recoded strains were turned into 8 strains, each with 1/8 of the genome recoded. Two of these strains had a dysfunctional tolC phenotype, meaning that it passed the positive-negative control selections. MAGE was used to reconstruct these strains from the ancestral strain (also had mutation). From this, 4 strains each with 1/4 of the genome and 80 codon modifications were created and conjugation into one strain was attempted. In the end, 28 of the 31 conjugations were accomplished, still falling short of providing entire-genome modification. If all TAG stop codons can be successfully replaced with TAA stop codons then it may be possible to use the TAA codon for other uses such as incorporation of unnatural amino acids.[6]

Other MAGE Applications

His-Tagging with MAGE

MAGE was used to simultaneously modify all of the translational machinery of E. coli, while maintaining functionality. Through 110 MAGE cycles, hexa-histidine tags were successfully added to the genes that code for all 38 translational proteins. The incorporation of His-tags into up to 8 different translation factors in a single strain does not dramatically affect the fitness of the cell. Additionally, three ribosomal subunit genes 50s, 30s, and 70s were his-tagged for purification of ribosomes using Ni-NTA. [3]

De-extinction

iGEM

The 2012 Yale iGEM team, led by Farren Isaacs, wanted to use a different bacterium, Acinetobacter baylyi ADP1, for MAGE because it is naturally competent. This would increase efficiency lost from cell death by electroporation and low electroporation transformation efficiency. In order to perform MAGE, they needed to knock out A. baylyi's mis-match repair system and construct a library of recombinases. To show that it works, they needed to construct an assay and design oligos to mutate the genome. Yale reported success in their stated goals, but did not report successful MAGE with A. baylyi.

Another team, 2012 Paris-Bettencourt, sought to perform MAGE by hand, i.e. without an automation device. The team reported extremely low efficiencies of recombination, even with purified oligos, and the side project was considered a failure.

References

Error fetching PMID 19633652:
Error fetching PMID 21764749:
  1. Error fetching PMID 19633652: [Wang2009]
    MAGE article
  2. Error fetching PMID 21764749: [Isaacs2011]
    CAGE article
All Medline abstracts: PubMed | HubMed