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Site-directed mutagenesis

February 16, 2024

Site-directed mutagenesis is a molecular biology method that is used to make specific and intentional mutating changes to the DNA sequence of a gene and any gene products. Also called site-specific mutagenesis or oligonucleotide-directed mutagenesis, it is used for investigating the structure and biological activity of DNA, RNA, and protein molecules, and for protein engineering.

Site-directed mutagenesis is one of the most important laboratory techniques for creating DNA libraries by introducing mutations into DNA sequences. There are numerous methods for achieving site-directed mutagenesis, but with decreasing costs of oligonucleotide synthesis, artificial gene synthesis is now occasionally used as an alternative to site-directed mutagenesis. Since 2013, the development of the CRISPR/Cas9 technology, based on a prokaryotic viral defense system, has also allowed for the editing of the genome, and mutagenesis may be performed in vivo with relative ease.[1]

History edit

Early attempts at mutagenesis using radiation or chemical mutagens were non-site-specific, generating random mutations.[2] Analogs of nucleotides and other chemicals were later used to generate localized point mutations,[3] examples of such chemicals are aminopurine,[4] nitrosoguanidine,[5] and bisulfite.[6] Site-directed mutagenesis was achieved in 1974 in the laboratory of Charles Weissmann using a nucleotide analogue N4-hydroxycytidine, which induces transition of GC to AT.[7][8] These methods of mutagenesis, however, are limited by the kind of mutation they can achieve, and they are not as specific as later site-directed mutagenesis methods.

In 1971, Clyde Hutchison and Marshall Edgell showed that it is possible to produce mutants with small fragments of phage ϕX174 and restriction nucleases.[9][10] Hutchison later produced with his collaborator Michael Smith in 1978 a more flexible approach to site-directed mutagenesis by using oligonucleotides in a primer extension method with DNA polymerase.[11] For his part in the development of this process, Michael Smith later shared the Nobel Prize in Chemistry in October 1993 with Kary B. Mullis, who invented polymerase chain reaction.

Basic mechanism edit

The basic procedure requires the synthesis of a short DNA primer. This synthetic primer contains the desired mutation and is complementary to the template DNA around the mutation site so it can hybridize with the DNA in the gene of interest. The mutation may be a single base change (a point mutation), multiple base changes, deletion, or insertion. The single-strand primer is then extended using a DNA polymerase, which copies the rest of the gene. The gene thus copied contains the mutated site, and is then introduced into a host cell in a vector and cloned. Finally, mutants are selected by DNA sequencing to check that they contain the desired mutation.

Approaches edit

The original method using single-primer extension was inefficient due to a low yield of mutants. This resulting mixture contains both the original unmutated template as well as the mutant strand, producing a mixed population of mutant and non-mutant progenies. Furthermore, the template used is methylated while the mutant strand is unmethylated, and the mutants may be counter-selected due to presence of mismatch repair system that favors the methylated template DNA, resulting in fewer mutants. Many approaches have since been developed to improve the efficiency of mutagenesis.

A large number of methods are available to effect site-directed mutagenesis,[12] although most of them have rarely been used in laboratories since the early 2000s, as newer techniques allow for simpler and easier ways of introducing site-specific mutation into genes.

Kunkel's method edit

In 1985, Thomas Kunkel introduced a technique that reduces the need to select for the mutants.[13] The DNA fragment to be mutated is inserted into a phagemid such as M13mp18/19 and is then transformed into an E. coli strain deficient in two enzymes, dUTPase (dut) and uracil deglycosidase (udg). Both enzymes are part of a DNA repair pathway that protects the bacterial chromosome from mutations by the spontaneous deamination of dCTP to dUTP. The dUTPase deficiency prevents the breakdown of dUTP, resulting in a high level of dUTP in the cell. The uracil deglycosidase deficiency prevents the removal of uracil from newly synthesized DNA. As the double-mutant E. coli replicates the phage DNA, its enzymatic machinery may, therefore, misincorporate dUTP instead of dTTP, resulting in single-strand DNA that contains some uracils (ssUDNA). The ssUDNA is extracted from the bacteriophage that is released into the medium, and then used as template for mutagenesis. An oligonucleotide containing the desired mutation is used for primer extension. The heteroduplex DNA, that forms, consists of one parental non-mutated strand containing dUTP and a mutated strand containing dTTP. The DNA is then transformed into an E. coli strain carrying the wildtype dut and udg genes. Here, the uracil-containing parental DNA strand is degraded, so that nearly all of the resulting DNA consists of the mutated strand.

Cassette mutagenesis edit

Unlike other methods, cassette mutagenesis need not involve primer extension using DNA polymerase. In this method, a fragment of DNA is synthesized, and then inserted into a plasmid.[14] It involves the cleavage by a restriction enzyme at a site in the plasmid and subsequent ligation of a pair of complementary oligonucleotides containing the mutation in the gene of interest to the plasmid. Usually, the restriction enzymes that cut at the plasmid and the oligonucleotide are the same, permitting sticky ends of the plasmid and insert to ligate to one another. This method can generate mutants at close to 100% efficiency, but is limited by the availability of suitable restriction sites flanking the site that is to be mutated.

PCR site-directed mutagenesis edit

 
Depiction of one common way to clone a site-directed mutagenesis library (i.e., using degenerate oligos). The gene of interest is PCRed with oligos that contain a region that is perfectly complementary to the template (blue), and one that differs from the template by one or more nucleotides (red). Many such primers containing degeneracy in the non-complementary region are pooled into the same PCR, resulting in many different PCR products with different mutations in that region (individual mutants shown with different colors below).

The limitation of restriction sites in cassette mutagenesis may be overcome using polymerase chain reaction with oligonucleotide "primers", such that a larger fragment may be generated, covering two convenient restriction sites. The exponential amplification in PCR produces a fragment containing the desired mutation in sufficient quantity to be separated from the original, unmutated plasmid by gel electrophoresis, which may then be inserted in the original context using standard recombinant molecular biology techniques. There are many variations of the same technique. The simplest method places the mutation site toward one of the ends of the fragment whereby one of two oligonucleotides used for generating the fragment contains the mutation. This involves a single step of PCR, but still has the inherent problem of requiring a suitable restriction site near the mutation site unless a very long primer is used. Other variations, therefore, employ three or four oligonucleotides, two of which may be non-mutagenic oligonucleotides that cover two convenient restriction sites and generate a fragment that can be digested and ligated into a plasmid, whereas the mutagenic oligonucleotide may be complementary to a location within that fragment well away from any convenient restriction site. These methods require multiple steps of PCR so that the final fragment to be ligated can contain the desired mutation. The design process for generating a fragment with the desired mutation and relevant restriction sites can be cumbersome. Software tools like SDM-Assist[15] can simplify the process.

Whole plasmid mutagenesis edit

For plasmid manipulations, other site-directed mutagenesis techniques have been supplanted largely by techniques that are highly efficient but relatively simple, easy to use, and commercially available as a kit. An example of these techniques is the "Quikchange" method,[16] wherein a pair of complementary mutagenic primers are used to amplify the entire plasmid in a thermocycling reaction using a high-fidelity non-strand-displacing DNA polymerase such as Pfu polymerase. The reaction generates a nicked, circular DNA. The template DNA must be eliminated by enzymatic digestion with a restriction enzyme such as DpnI, which is specific for methylated DNA. All DNA produced from most Escherichia coli strains would be methylated; the template plasmid that is biosynthesized in E. coli will, therefore, be digested, while the mutated plasmid, which is generated in vitro and is therefore unmethylated, would be left undigested. Note that, in these double-strand plasmid mutagenesis methods, while the thermocycling reaction may be used, the DNA is not exponentially amplified if the two primers are designed such that they bind symmetrically to the same region around the mutagenesis site, as described in the original protocol. In this case the amplification is linear, and it is therefore inaccurate to describe the procedure as a PCR, since there is no chain reaction. However, if the primers are designed to bind in an offset manner such that mutagenesis site is close to the 5' end of both primers, the 3' region of the primers can bind also to the amplified products and thus exponential product formation is observed. The name "Quikchange" originates from the registered trademark "QuikChange mutagenesis" of Stratagene, now Agilent Technologies , for site directed mutagenesis kits. The method was developed by scientists working at Stratagene.[16]

Note that Pfu polymerase can become strand-displacing at higher extension temperature (≥70 °C) which can result in the failure of the experiment, therefore the extension reaction should be performed at the recommended temperature of 68 °C. In some applications, this method has been observed to lead to insertion of multiple copies of primers.[17] A variation of this method, called SPRINP, prevents this artifact and has been used in different types of site directed mutagenesis.[17]

Other techniques such as scanning mutagenesis of oligo-directed targets (SMOOT) can semi-randomly combine mutagenic oligonucleotides in plasmid mutagenesis.[18] This technique can create plasmid mutagenesis libraries ranging from single mutations to comprehensive codon mutagenesis across an entire gene.

In vivo site-directed mutagenesis methods edit

  • Delitto perfetto[19]
  • Transplacement "pop-in pop-out"
  • Direct gene deletion and site-specific mutagenesis with PCR and one recyclable marker
  • Direct gene deletion and site-specific mutagenesis with PCR and one recyclable marker using long homologous regions
  • In vivo site-directed mutagenesis with synthetic oligonucleotides[20]

CRISPR edit

Main article: CRISPR gene editing

Since 2013, the development of CRISPR-Cas9 technology has allowed for the efficient introduction of various mutations into the genome of a wide variety of organisms. The method does not require a transposon insertion site, leaves no marker, and its efficiency and simplicity has made it the preferred method for genome editing.[21][22]

Applications edit

 
Site saturation mutagenesis is a type of site-directed mutagenesis. This image shows the saturation mutagenesis of a single position in a theoretical 10-residue protein. The wild type version of the protein is shown at the top, with M representing the first amino acid methionine, and * representing the termination of translation. All 19 mutants of the isoleucine at position 5 are shown below.

Site-directed mutagenesis is used to generate mutations that may produce a rationally designed protein that has improved or special properties (i.e.protein engineering).

Investigative tools – specific mutations in DNA allow the function and properties of a DNA sequence or a protein to be investigated in a rational approach. Furthermore, single amino-acid changes by site-directed mutagenesis in proteins can help understand the importance of post-translational modifications. For instance changing a particular serine (phosphoacceptor) to an alanine (phospho-non-acceptor) in a substrate protein blocks the attachment of a phosphate group, thereby allows the phosphorylation to be investigated. This approach has been used to uncover the phosphorylation of the protein CBP by the kinase HIPK2[23] Another comprehensive approach is site saturation mutagenesis where one codon or a set of codons may be substituted with all possible amino acids at the specific positions.[24]

Commercial applications – Proteins may be engineered to produce mutant forms that are tailored for a specific application. For example, commonly used laundry detergents may contain subtilisin, whose wild-type form has a methionine that can be oxidized by bleach, significantly reducing the activity the protein in the process.[25] This methionine may be replaced by alanine or other residues, making it resistant to oxidation thereby keeping the protein active in the presence of bleach.[26]

Gene synthesis edit

As the cost of DNA oligonucleotides synthesis falls, artificial synthesis of a complete gene is now a viable method for introducing mutation into gene. This method allows for extensive mutagenesis over multiples sites, including the complete redesign of the codon usage of gene to optimise it for a particular organism.[27]

See also edit

References edit

  1. ^ Hsu PD, Lander ES, Zhang F (June 2014). "Development and applications of CRISPR-Cas9 for genome engineering". Cell. 157 (6): 1262–78. doi:10.1016/j.cell.2014.05.010. PMC 4343198. PMID 24906146.
  2. ^ Kilbey, B. J. (1995). "Charlotte Auerbach (1899-1994)". Genetics. 141 (1): 1–5. doi:10.1093/genetics/141.1.1. PMC 1206709. PMID 8536959.
  3. ^ Shortle, D.; Dimaio, D.; Nathans, D. (1981). "Directed Mutagenesis". Annual Review of Genetics. 15: 265–294. doi:10.1146/annurev.ge.15.120181.001405. PMID 6279018.
  4. ^ Caras, I. W.; MacInnes, M. A.; Persing, D. H.; Coffino, P.; Martin Jr, D. W. (1982). "Mechanism of 2-aminopurine mutagenesis in mouse T-lymphosarcoma cells". Molecular and Cellular Biology. 2 (9): 1096–1103. doi:10.1128/MCB.2.9.1096. PMC 369902. PMID 6983647.
  5. ^ McHugh, G. L.; Miller, C. G. (1974). "Isolation and Characterization of Proline Peptidase Mutants of Salmonella typhimurium". Journal of Bacteriology. 120 (1): 364–371. doi:10.1128/JB.120.1.364-371.1974. PMC 245771. PMID 4607625.
  6. ^ D Shortle & D Nathans (1978). "Local mutagenesis: a method for generating viral mutants with base substitutions in preselected regions of the viral genome". Proceedings of the National Academy of Sciences. 75 (5): 2170–2174. Bibcode:1978PNAS...75.2170S. doi:10.1073/pnas.75.5.2170. PMC 392513. PMID 209457.
  7. ^ R A Flavell; D L Sabo; E F Bandle & C Weissmann (1975). "Site-directed mutagenesis: effect of an extracistronic mutation on the in vitro propagation of bacteriophage Qbeta RNA". Proc Natl Acad Sci U S A. 72 (1): 367–371. Bibcode:1975PNAS...72..367F. doi:10.1073/pnas.72.1.367. PMC 432306. PMID 47176.
  8. ^ Willi Müller; Hans Weber; François Meyer; Charles Weissmann (1978). "Site-directed mutagenesis in DNA: Generation of point mutations in cloned β globin complementary DNA at the positions corresponding to amino acids 121 to 123". Journal of Molecular Biology. 124 (2): 343–358. doi:10.1016/0022-2836(78)90303-0. PMID 712841.
  9. ^ Hutchison III, C.A.; Edgell, M. H. (1971). "Genetic Assay for Small Fragments of Bacteriophage φX174 Deoxyribonucleic Acid". Journal of Virology. 8 (2): 181–189. doi:10.1128/JVI.8.2.181-189.1971. PMC 356229. PMID 4940243.
  10. ^ Marshall H. Edgell, Clyde A. Hutchison, III, and Morton Sclair (1972). "Specific Endonuclease R Fragments of Bacteriophage X174 Deoxyribonucleic Acid". Journal of Virology. 9 (4): 574–582. doi:10.1128/JVI.9.4.574-582.1972. PMC 356341. PMID 4553678.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  11. ^ Hutchison CA, Phillips S, Edgell MH, Gillam S, Jahnke P, Smith M (September 1978). "Mutagenesis at a specific position in a DNA sequence" (PDF). J. Biol. Chem. 253 (18): 6551–60. doi:10.1016/S0021-9258(19)46967-6. PMID 681366.
  12. ^ Braman, Jeff, ed. (2002). In Vitro Mutagenesis Protocols. Methods in Molecular Biology. Vol. 182 (2nd ed.). Humana Press. ISBN 978-0896039100.
  13. ^ Kunkel TA. (1985). "Rapid and efficient site-specific mutagenesis without phenotypic selection". Proceedings of the National Academy of Sciences. 82 (2): 488–92. Bibcode:1985PNAS...82..488K. doi:10.1073/pnas.82.2.488. PMC 397064. PMID 3881765.
  14. ^ Wells, J. A.; Estell, D. A. (1988). "Subtilisin--an enzyme designed to be engineered". Trends in Biochemical Sciences. 13 (8): 291–297. doi:10.1016/0968-0004(88)90121-1. PMID 3154281.
  15. ^ Karnik, Abhijit; Karnik, Rucha; Grefen, Christopher (2013). "SDM-Assist software to design site-directed mutagenesis primers introducing "silent" restriction sites". BMC Bioinformatics. 14 (1): 105. doi:10.1186/1471-2105-14-105. ISSN 1471-2105. PMC 3644487. PMID 23522286.
  16. ^ a b Papworth, C., Bauer, J. C., Braman, J. and Wright, D. A. (1996). "Site-directed mutagenesis in one day with >80% efficiency". Strategies. 9 (3): 3–4.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  17. ^ a b Edelheit, O; Hanukoglu, A; Hanukoglu, I (2009). "Simple and efficient site-directed mutagenesis using two single-primer reactions in parallel to generate mutants for protein structure-function studies". BMC Biotechnol. 9: 61. doi:10.1186/1472-6750-9-61. PMC 2711942. PMID 19566935.
  18. ^ Cerchione, Derek; Loveluck, Katherine; Tillotson, Eric L.; Harbinski, Fred; DaSilva, Jen; Kelley, Chase P.; Keston-Smith, Elise; Fernandez, Cecilia A.; Myer, Vic E.; Jayaram, Hariharan; Steinberg, Barrett E. (16 April 2020). "SMOOT libraries and phage-induced directed evolution of Cas9 to engineer reduced off-target activity". PLOS ONE. 15 (4): e0231716. Bibcode:2020PLoSO..1531716C. doi:10.1371/journal.pone.0231716. ISSN 1932-6203. PMC 7161989. PMID 32298334.
  19. ^ Storici F.; Resnick MA. (2006). The delitto perfetto approach to in vivo site-directed mutagenesis and chromosome rearrangements with synthetic oligonucleotides in yeast. Methods in Enzymology. Vol. 409. pp. 329–45. doi:10.1016/S0076-6879(05)09019-1. ISBN 9780121828141. PMID 16793410.
  20. ^ Storici F.; Resnick MA (2003). "Delitto perfetto targeted mutagenesis in yeast with oligonucleotides". Genetic Engineering. 25: 189–207. PMID 15260239.
  21. ^ Damien Biot-Pelletier; Vincent J. J. Martin (2016). "Seamless site-directed mutagenesis of the Saccharomyces cerevisiae genome using CRISPR-Cas9". Journal of Biological Engineering. 10: 6. doi:10.1186/s13036-016-0028-1. PMC 4850645. PMID 27134651.
  22. ^ Xu S (20 August 2015). "The application of CRISPR-Cas9 genome editing in Caenorhabditis elegans". J Genet Genomics. 42 (8): 413–21. doi:10.1016/j.jgg.2015.06.005. PMC 4560834. PMID 26336798.
  23. ^ Kovács KA, Steinmann M, Halfon O, Magistretti PJ, Cardinaux JR (November 2015). "Complex regulation of CREB-binding protein by homeodomain-interacting protein kinase 2" (PDF). Cellular Signalling. 27 (11): 2252–60. doi:10.1016/j.cellsig.2015.08.001. PMID 26247811.
  24. ^ Reetz, M. T.; Carballeira J. D. (2007). "Iterative saturation mutagenesis (ISM) for rapid directed evolution of functional enzymes". Nature Protocols. 2 (4): 891–903. doi:10.1038/nprot.2007.72. PMID 17446890. S2CID 37361631.
  25. ^ Stauffer CE, Etson D (October 10, 1969). "The effect on subtilisin activity of oxidizing a methionine residue". Journal of Biological Chemistry. 244 (19): 5333–8. doi:10.1016/S0021-9258(18)63664-6. PMID 5344139.
  26. ^ Estell DA, Graycar TP, Wells JA (10 June 1985). "Engineering an enzyme by site-directed mutagenesis to be resistant to chemical oxidation". Journal of Biological Chemistry. 260 (11): 6518–21. doi:10.1016/S0021-9258(18)88811-1. PMID 3922976.
  27. ^ Yury E. Khudyakov, Howard A. Fields, ed. (25 September 2002). Artificial DNA: Methods and Applications. CRC Press. p. 13. ISBN 9781420040166.

External links edit

  • Nobel Lecture on Invention of Site-Directed Mutagenesis
  • OpenWetWare

February 16, 2024
site, directed, mutagenesis, molecular, biology, method, that, used, make, specific, intentional, mutating, changes, sequence, gene, gene, products, also, called, site, specific, mutagenesis, oligonucleotide, directed, mutagenesis, used, investigating, structu. Site directed mutagenesis is a molecular biology method that is used to make specific and intentional mutating changes to the DNA sequence of a gene and any gene products Also called site specific mutagenesis or oligonucleotide directed mutagenesis it is used for investigating the structure and biological activity of DNA RNA and protein molecules and for protein engineering Site directed mutagenesis is one of the most important laboratory techniques for creating DNA libraries by introducing mutations into DNA sequences There are numerous methods for achieving site directed mutagenesis but with decreasing costs of oligonucleotide synthesis artificial gene synthesis is now occasionally used as an alternative to site directed mutagenesis Since 2013 the development of the CRISPR Cas9 technology based on a prokaryotic viral defense system has also allowed for the editing of the genome and mutagenesis may be performed in vivo with relative ease 1 Contents 1 History 2 Basic mechanism 3 Approaches 3 1 Kunkel s method 3 2 Cassette mutagenesis 3 3 PCR site directed mutagenesis 3 4 Whole plasmid mutagenesis 3 5 In vivo site directed mutagenesis methods 3 6 CRISPR 4 Applications 5 Gene synthesis 6 See also 7 References 8 External linksHistory editEarly attempts at mutagenesis using radiation or chemical mutagens were non site specific generating random mutations 2 Analogs of nucleotides and other chemicals were later used to generate localized point mutations 3 examples of such chemicals are aminopurine 4 nitrosoguanidine 5 and bisulfite 6 Site directed mutagenesis was achieved in 1974 in the laboratory of Charles Weissmann using a nucleotide analogue N4 hydroxycytidine which induces transition of GC to AT 7 8 These methods of mutagenesis however are limited by the kind of mutation they can achieve and they are not as specific as later site directed mutagenesis methods In 1971 Clyde Hutchison and Marshall Edgell showed that it is possible to produce mutants with small fragments of phage ϕX174 and restriction nucleases 9 10 Hutchison later produced with his collaborator Michael Smith in 1978 a more flexible approach to site directed mutagenesis by using oligonucleotides in a primer extension method with DNA polymerase 11 For his part in the development of this process Michael Smith later shared the Nobel Prize in Chemistry in October 1993 with Kary B Mullis who invented polymerase chain reaction Basic mechanism editThe basic procedure requires the synthesis of a short DNA primer This synthetic primer contains the desired mutation and is complementary to the template DNA around the mutation site so it can hybridize with the DNA in the gene of interest The mutation may be a single base change a point mutation multiple base changes deletion or insertion The single strand primer is then extended using a DNA polymerase which copies the rest of the gene The gene thus copied contains the mutated site and is then introduced into a host cell in a vector and cloned Finally mutants are selected by DNA sequencing to check that they contain the desired mutation Approaches editThe original method using single primer extension was inefficient due to a low yield of mutants This resulting mixture contains both the original unmutated template as well as the mutant strand producing a mixed population of mutant and non mutant progenies Furthermore the template used is methylated while the mutant strand is unmethylated and the mutants may be counter selected due to presence of mismatch repair system that favors the methylated template DNA resulting in fewer mutants Many approaches have since been developed to improve the efficiency of mutagenesis A large number of methods are available to effect site directed mutagenesis 12 although most of them have rarely been used in laboratories since the early 2000s as newer techniques allow for simpler and easier ways of introducing site specific mutation into genes Kunkel s method edit In 1985 Thomas Kunkel introduced a technique that reduces the need to select for the mutants 13 The DNA fragment to be mutated is inserted into a phagemid such as M13mp18 19 and is then transformed into an E coli strain deficient in two enzymes dUTPase dut and uracil deglycosidase udg Both enzymes are part of a DNA repair pathway that protects the bacterial chromosome from mutations by the spontaneous deamination of dCTP to dUTP The dUTPase deficiency prevents the breakdown of dUTP resulting in a high level of dUTP in the cell The uracil deglycosidase deficiency prevents the removal of uracil from newly synthesized DNA As the double mutant E coli replicates the phage DNA its enzymatic machinery may therefore misincorporate dUTP instead of dTTP resulting in single strand DNA that contains some uracils ssUDNA The ssUDNA is extracted from the bacteriophage that is released into the medium and then used as template for mutagenesis An oligonucleotide containing the desired mutation is used for primer extension The heteroduplex DNA that forms consists of one parental non mutated strand containing dUTP and a mutated strand containing dTTP The DNA is then transformed into an E coli strain carrying the wildtype dut and udg genes Here the uracil containing parental DNA strand is degraded so that nearly all of the resulting DNA consists of the mutated strand Cassette mutagenesis edit Unlike other methods cassette mutagenesis need not involve primer extension using DNA polymerase In this method a fragment of DNA is synthesized and then inserted into a plasmid 14 It involves the cleavage by a restriction enzyme at a site in the plasmid and subsequent ligation of a pair of complementary oligonucleotides containing the mutation in the gene of interest to the plasmid Usually the restriction enzymes that cut at the plasmid and the oligonucleotide are the same permitting sticky ends of the plasmid and insert to ligate to one another This method can generate mutants at close to 100 efficiency but is limited by the availability of suitable restriction sites flanking the site that is to be mutated PCR site directed mutagenesis edit nbsp Depiction of one common way to clone a site directed mutagenesis library i e using degenerate oligos The gene of interest is PCRed with oligos that contain a region that is perfectly complementary to the template blue and one that differs from the template by one or more nucleotides red Many such primers containing degeneracy in the non complementary region are pooled into the same PCR resulting in many different PCR products with different mutations in that region individual mutants shown with different colors below The limitation of restriction sites in cassette mutagenesis may be overcome using polymerase chain reaction with oligonucleotide primers such that a larger fragment may be generated covering two convenient restriction sites The exponential amplification in PCR produces a fragment containing the desired mutation in sufficient quantity to be separated from the original unmutated plasmid by gel electrophoresis which may then be inserted in the original context using standard recombinant molecular biology techniques There are many variations of the same technique The simplest method places the mutation site toward one of the ends of the fragment whereby one of two oligonucleotides used for generating the fragment contains the mutation This involves a single step of PCR but still has the inherent problem of requiring a suitable restriction site near the mutation site unless a very long primer is used Other variations therefore employ three or four oligonucleotides two of which may be non mutagenic oligonucleotides that cover two convenient restriction sites and generate a fragment that can be digested and ligated into a plasmid whereas the mutagenic oligonucleotide may be complementary to a location within that fragment well away from any convenient restriction site These methods require multiple steps of PCR so that the final fragment to be ligated can contain the desired mutation The design process for generating a fragment with the desired mutation and relevant restriction sites can be cumbersome Software tools like SDM Assist 15 can simplify the process Whole plasmid mutagenesis edit For plasmid manipulations other site directed mutagenesis techniques have been supplanted largely by techniques that are highly efficient but relatively simple easy to use and commercially available as a kit An example of these techniques is the Quikchange method 16 wherein a pair of complementary mutagenic primers are used to amplify the entire plasmid in a thermocycling reaction using a high fidelity non strand displacing DNA polymerase such as Pfu polymerase The reaction generates a nicked circular DNA The template DNA must be eliminated by enzymatic digestion with a restriction enzyme such as DpnI which is specific for methylated DNA All DNA produced from most Escherichia coli strains would be methylated the template plasmid that is biosynthesized in E coli will therefore be digested while the mutated plasmid which is generated in vitro and is therefore unmethylated would be left undigested Note that in these double strand plasmid mutagenesis methods while the thermocycling reaction may be used the DNA is not exponentially amplified if the two primers are designed such that they bind symmetrically to the same region around the mutagenesis site as described in the original protocol In this case the amplification is linear and it is therefore inaccurate to describe the procedure as a PCR since there is no chain reaction However if the primers are designed to bind in an offset manner such that mutagenesis site is close to the 5 end of both primers the 3 region of the primers can bind also to the amplified products and thus exponential product formation is observed The name Quikchange originates from the registered trademark QuikChange mutagenesis of Stratagene now Agilent Technologies for site directed mutagenesis kits The method was developed by scientists working at Stratagene 16 Note that Pfu polymerase can become strand displacing at higher extension temperature 70 C which can result in the failure of the experiment therefore the extension reaction should be performed at the recommended temperature of 68 C In some applications this method has been observed to lead to insertion of multiple copies of primers 17 A variation of this method called SPRINP prevents this artifact and has been used in different types of site directed mutagenesis 17 Other techniques such as scanning mutagenesis of oligo directed targets SMOOT can semi randomly combine mutagenic oligonucleotides in plasmid mutagenesis 18 This technique can create plasmid mutagenesis libraries ranging from single mutations to comprehensive codon mutagenesis across an entire gene In vivo site directed mutagenesis methods edit Delitto perfetto 19 Transplacement pop in pop out Direct gene deletion and site specific mutagenesis with PCR and one recyclable marker Direct gene deletion and site specific mutagenesis with PCR and one recyclable marker using long homologous regions In vivo site directed mutagenesis with synthetic oligonucleotides 20 CRISPR edit Main article CRISPR gene editing Since 2013 the development of CRISPR Cas9 technology has allowed for the efficient introduction of various mutations into the genome of a wide variety of organisms The method does not require a transposon insertion site leaves no marker and its efficiency and simplicity has made it the preferred method for genome editing 21 22 Applications edit nbsp Site saturation mutagenesis is a type of site directed mutagenesis This image shows the saturation mutagenesis of a single position in a theoretical 10 residue protein The wild type version of the protein is shown at the top with M representing the first amino acid methionine and representing the termination of translation All 19 mutants of the isoleucine at position 5 are shown below Site directed mutagenesis is used to generate mutations that may produce a rationally designed protein that has improved or special properties i e protein engineering Investigative tools specific mutations in DNA allow the function and properties of a DNA sequence or a protein to be investigated in a rational approach Furthermore single amino acid changes by site directed mutagenesis in proteins can help understand the importance of post translational modifications For instance changing a particular serine phosphoacceptor to an alanine phospho non acceptor in a substrate protein blocks the attachment of a phosphate group thereby allows the phosphorylation to be investigated This approach has been used to uncover the phosphorylation of the protein CBP by the kinase HIPK2 23 Another comprehensive approach is site saturation mutagenesis where one codon or a set of codons may be substituted with all possible amino acids at the specific positions 24 Commercial applications Proteins may be engineered to produce mutant forms that are tailored for a specific application For example commonly used laundry detergents may contain subtilisin whose wild type form has a methionine that can be oxidized by bleach significantly reducing the activity the protein in the process 25 This methionine may be replaced by alanine or other residues making it resistant to oxidation thereby keeping the protein active in the presence of bleach 26 Gene synthesis editAs the cost of DNA oligonucleotides synthesis falls artificial synthesis of a complete gene is now a viable method for introducing mutation into gene This method allows for extensive mutagenesis over multiples sites including the complete redesign of the codon usage of gene to optimise it for a particular organism 27 See also editDirected mutagenesis Phi value analysisReferences edit Hsu PD Lander ES Zhang F June 2014 Development and applications of CRISPR Cas9 for genome engineering Cell 157 6 1262 78 doi 10 1016 j cell 2014 05 010 PMC 4343198 PMID 24906146 Kilbey B J 1995 Charlotte Auerbach 1899 1994 Genetics 141 1 1 5 doi 10 1093 genetics 141 1 1 PMC 1206709 PMID 8536959 Shortle D Dimaio D Nathans D 1981 Directed Mutagenesis Annual Review of Genetics 15 265 294 doi 10 1146 annurev ge 15 120181 001405 PMID 6279018 Caras I W MacInnes M A Persing D H Coffino P Martin Jr D W 1982 Mechanism of 2 aminopurine mutagenesis in mouse T lymphosarcoma cells Molecular and Cellular Biology 2 9 1096 1103 doi 10 1128 MCB 2 9 1096 PMC 369902 PMID 6983647 McHugh G L Miller C G 1974 Isolation and Characterization of Proline Peptidase Mutants of Salmonella typhimurium Journal of Bacteriology 120 1 364 371 doi 10 1128 JB 120 1 364 371 1974 PMC 245771 PMID 4607625 D Shortle amp D Nathans 1978 Local mutagenesis a method for generating viral mutants with base substitutions in preselected regions of the viral genome Proceedings of the National Academy of Sciences 75 5 2170 2174 Bibcode 1978PNAS 75 2170S doi 10 1073 pnas 75 5 2170 PMC 392513 PMID 209457 R A Flavell D L Sabo E F Bandle amp C Weissmann 1975 Site directed mutagenesis effect of an extracistronic mutation on the in vitro propagation of bacteriophage Qbeta RNA Proc Natl Acad Sci U S A 72 1 367 371 Bibcode 1975PNAS 72 367F doi 10 1073 pnas 72 1 367 PMC 432306 PMID 47176 Willi Muller Hans Weber Francois Meyer Charles Weissmann 1978 Site directed mutagenesis in DNA Generation of point mutations in cloned b globin complementary DNA at the positions corresponding to amino acids 121 to 123 Journal of Molecular Biology 124 2 343 358 doi 10 1016 0022 2836 78 90303 0 PMID 712841 Hutchison III C A Edgell M H 1971 Genetic Assay for Small Fragments of Bacteriophage fX174 Deoxyribonucleic Acid Journal of Virology 8 2 181 189 doi 10 1128 JVI 8 2 181 189 1971 PMC 356229 PMID 4940243 Marshall H Edgell Clyde A Hutchison III and Morton Sclair 1972 Specific Endonuclease R Fragments of Bacteriophage X174 Deoxyribonucleic Acid Journal of Virology 9 4 574 582 doi 10 1128 JVI 9 4 574 582 1972 PMC 356341 PMID 4553678 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Hutchison CA Phillips S Edgell MH Gillam S Jahnke P Smith M September 1978 Mutagenesis at a specific position in a DNA sequence PDF J Biol Chem 253 18 6551 60 doi 10 1016 S0021 9258 19 46967 6 PMID 681366 Braman Jeff ed 2002 In Vitro Mutagenesis Protocols Methods in Molecular Biology Vol 182 2nd ed Humana Press ISBN 978 0896039100 Kunkel TA 1985 Rapid and efficient site specific mutagenesis without phenotypic selection Proceedings of the National Academy of Sciences 82 2 488 92 Bibcode 1985PNAS 82 488K doi 10 1073 pnas 82 2 488 PMC 397064 PMID 3881765 Wells J A Estell D A 1988 Subtilisin an enzyme designed to be engineered Trends in Biochemical Sciences 13 8 291 297 doi 10 1016 0968 0004 88 90121 1 PMID 3154281 Karnik Abhijit Karnik Rucha Grefen Christopher 2013 SDM Assist software to design site directed mutagenesis primers introducing silent restriction sites BMC Bioinformatics 14 1 105 doi 10 1186 1471 2105 14 105 ISSN 1471 2105 PMC 3644487 PMID 23522286 a b Papworth C Bauer J C Braman J and Wright D A 1996 Site directed mutagenesis in one day with gt 80 efficiency Strategies 9 3 3 4 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link a b Edelheit O Hanukoglu A Hanukoglu I 2009 Simple and efficient site directed mutagenesis using two single primer reactions in parallel to generate mutants for protein structure function studies BMC Biotechnol 9 61 doi 10 1186 1472 6750 9 61 PMC 2711942 PMID 19566935 Cerchione Derek Loveluck Katherine Tillotson Eric L Harbinski Fred DaSilva Jen Kelley Chase P Keston Smith Elise Fernandez Cecilia A Myer Vic E Jayaram Hariharan Steinberg Barrett E 16 April 2020 SMOOT libraries and phage induced directed evolution of Cas9 to engineer reduced off target activity PLOS ONE 15 4 e0231716 Bibcode 2020PLoSO 1531716C doi 10 1371 journal pone 0231716 ISSN 1932 6203 PMC 7161989 PMID 32298334 Storici F Resnick MA 2006 The delitto perfetto approach to in vivo site directed mutagenesis and chromosome rearrangements with synthetic oligonucleotides in yeast Methods in Enzymology Vol 409 pp 329 45 doi 10 1016 S0076 6879 05 09019 1 ISBN 9780121828141 PMID 16793410 Storici F Resnick MA 2003 Delitto perfetto targeted mutagenesis in yeast with oligonucleotides Genetic Engineering 25 189 207 PMID 15260239 Damien Biot Pelletier Vincent J J Martin 2016 Seamless site directed mutagenesis of the Saccharomyces cerevisiae genome using CRISPR Cas9 Journal of Biological Engineering 10 6 doi 10 1186 s13036 016 0028 1 PMC 4850645 PMID 27134651 Xu S 20 August 2015 The application of CRISPR Cas9 genome editing in Caenorhabditis elegans J Genet Genomics 42 8 413 21 doi 10 1016 j jgg 2015 06 005 PMC 4560834 PMID 26336798 Kovacs KA Steinmann M Halfon O Magistretti PJ Cardinaux JR November 2015 Complex regulation of CREB binding protein by homeodomain interacting protein kinase 2 PDF Cellular Signalling 27 11 2252 60 doi 10 1016 j cellsig 2015 08 001 PMID 26247811 Reetz M T Carballeira J D 2007 Iterative saturation mutagenesis ISM for rapid directed evolution of functional enzymes Nature Protocols 2 4 891 903 doi 10 1038 nprot 2007 72 PMID 17446890 S2CID 37361631 Stauffer CE Etson D October 10 1969 The effect on subtilisin activity of oxidizing a methionine residue Journal of Biological Chemistry 244 19 5333 8 doi 10 1016 S0021 9258 18 63664 6 PMID 5344139 Estell DA Graycar TP Wells JA 10 June 1985 Engineering an enzyme by site directed mutagenesis to be resistant to chemical oxidation Journal of Biological Chemistry 260 11 6518 21 doi 10 1016 S0021 9258 18 88811 1 PMID 3922976 Yury E Khudyakov Howard A Fields ed 25 September 2002 Artificial DNA Methods and Applications CRC Press p 13 ISBN 9781420040166 External links editNobel Lecture on Invention of Site Directed Mutagenesis OpenWetWare Diagram summarizing site directed mutagenesis Retrieved from https en wikipedia org w index php title Site directed mutagenesis amp oldid 1186482498, wikipedia, wiki, book, books, library,

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