Genetic engineering techniques
Genetic engineering techniques enable modification of the DNA of living organisms. A variety of editing techniques have been developed since DNA's structure was first discovered.
Targets
Bacteria are commonly engineered for research purposes. Typically this is through transformation to add a plasmid containing a gene of interest, but editing of the chromosome is also used. Plants and animals have both been genetically modified for research, agricultural and medical applications. In plants, the most widely inserted genes provide herbicide resistance or insecticidal properties.[1] In animals, the most widely used are growth hormone genes. Finally, genetically modified viruses (such as retroviruses and lentiviruses[2]) are also used as viral vectors to transfer target genes to another organism in gene therapy.
Procedure
The first step involves choosing and isolating the gene that will be inserted into/removed from the genetically modified organism.
The gene must generally be combined with a promoter and terminator region as well as a selectable marker gene.
Then the genes must be spliced into the target's DNA. For animals, the gene must be inserted into embryonic stem cells.
The resulting organism must have the presence of the target gene confirmed.
First generation offspring are heterozygous, requiring them to be inbred to create the homozygous pattern necessary for stable inheritance. Homozygosity must be confirmed in second generation specimens, which then become the final product.
History
Human directed genetic manipulation began with the domestication of plants and animals through artificial selection in about 12,000 BC.[3]:1 Various techniques were developed to aid in breeding and selection. Hybridization was one way rapid changes in an organisms makeup could be introduced. Hybridization most likely first occurred when humans first grew similar, yet slightly different plants in close proximity.[4]:32 Some plants were able to be propagated by vegetative cloning.[4]:31 X-rays were first used to deliberately mutate plants in 1927. Between 1927 and 2017, more than 3,248 genetically mutated plant varieties had been produced using x-rays.[5]
It wasn't until the mid 1800s that DNA and genes were discovered, which would form the basis of modern genetic manipulation. Genetic inheritance was first discovered by Gregor Mendel in 1865 following experiments crossing peas.[6] In 1928 Frederick Griffith proved the existence of a "transforming principle" involved in inheritance, which was identified as DNA in 1944 by Oswald Avery, Colin MacLeod, and Maclyn McCarty. Frederick Sanger developed a method for sequencing DNA in 1977, greatly increasing the genetic information available to researchers.
As well as discovering how DNA works, tools had to be developed that allowed it to be manipulated. In 1970 Hamilton Smiths lab discovered restriction enzymes, enabling scientists to isolate genes from an organism's genome.[7] DNA ligases, that join broken DNA together, had been discovered earlier in 1967[8] and by combining the two enzymes it was possible to "cut and paste" DNA sequences to create recombinant DNA. Plasmids, discovered in 1952,[9] became important tools for transferring information between cells and replicating DNA sequences. Polymerase chain reaction (PCR), developed by Kary Mullis in 1983, allowed small sections of DNA to be amplified and aided identification and isolation of genetic material.
As well as manipulating the DNA, techniques had to be developed for its insertion (known as transformation) into an organism's genome. Griffiths experiment had already shown that some bacteria had the ability to naturally uptake and express foreign DNA. Artificial competence was induced in Escherichia coli in 1970 by treating them with calcium chloride solution (CaCl2).[10] Transformation using electroporation was developed in the late 1980s, increasing the efficiency and bacterial range.[11] In 1907 a bacterium that caused plant tumors, Agrobacterium tumefaciens, had been discovered and in the early 1970s it was found that the bacteria inserted its DNA into plants using a Ti plasmid.[12] By removing the genes in the plasmid that caused the tumor and adding in novel genes researchers were able to infect plants with A. tumefaciens and let the bacteria insert their chosen DNA into the genomes of the plants.[13]
An important part of genetic engineering is to identify useful genes to transform into the genetically modified organism. The bacteria Bacillus thuringiensis was first discovered in 1901 as the causative agent in the death of silkworms. Due to these insecticidal properties the bacteria was used as an biological insecticide, commercially developed in 1938. The cry proteins were discovered to provide the insecticidal activity in 1956 and by the 1980s scientists had successfully cloned the gene coding for this protein and expressed it in plants.[14] The gene that provides resistance to the glyphosate herbicide was found, after seven years searching, in the outflow pipe of a Monsanto roundup manufacturing facility.[15] In animals the majority of genes used are growth hormone genes.[16]
Libraries
Target genes can be cloned from a DNA segment after the creation of a DNA library. The libraries generally cover the organism's genome multiple times and its size will depend on how large the genome is.
Techniques
Gene isolation
The DNA is first digested with a random digestion method, commonly by cutting the DNA with restriction enzymes (enzymes that cut DNA). A partial restriction digest cuts only some of the restriction sites, resulting in overlapping DNA fragment lengths. The DNA fragments are put into individual plasmid vectors and grown inside bacteria. Once in the bacteria the plasmid is copied as the bacteria divides. To determine if a useful gene is present on a particular fragment the bacterial library is screened for the desired phenotype. If the phenotype is detected then it is possible that the bacteria contains the target gene. If the gene does not have a detectable phenotype or a DNA library does not contain the correct gene, other methods can be used to isolate it. If the position of the gene can be determined using molecular markers then chromosome walking is one way to isolate the correct DNA fragment. If the gene expresses close homology to a known gene in another species, then it could be isolated by searching for genes in the library that closely match the known gene.[17]
If the DNA sequence of the gene and the organism is known, restriction enzymes can cut the DNA on either side of the gene and gel electrophoresis can sort the fragments according to length.[18] The DNA band at the correct size should contain the gene, where it can be excised from the gel. Polymerase chain reaction (PCR) can be used to amplify the gene, which can then be isolated through gel electrophoresis.[19] It is also possible to synthesize the gene.[20]
The gene to be inserted into the genetically modified organism must be combined with other genetic elements in order for it to work properly. The gene can also be modified at this stage for better expression or effectiveness. As well as the gene to be inserted most constructs contain a promoter and terminator region as well as a selectable marker gene. The promoter region initiates transcription of the gene and can be used to control the location and level of gene expression, while the terminator region ends transcription. The selectable marker, which in most cases confers antibiotic resistance to the organism it is expressed in, is needed to determine which cells are transformed with the new gene. The constructs are made using recombinant DNA techniques, such as restriction digests, ligations and molecular cloning.[21]
Gene targeting
Gene targeting uses homologous recombination to target desired changes to a specific endogenous gene. This tends to occur at a relatively low frequency in plants and animals and generally requires the use of selectable markers. The success of gene targeting can be enhanced with the use of engineered nucleases such as zinc finger nucleases,[22][23] engineered homing endonucleases,[24][25] transcription activator-like effector nuclease.[26][27] or CRISPR. Engineered nucleases can also introduce mutations at endogenous genes that generate a gene knockout.[28][29]
Transformation
About 1% of bacteria are naturally able to take up foreign DNA, but this ability can be induced in other bacteria.[30] Stressing the bacteria with a heat shock or an electric shock can make the cell membrane permeable to DNA that may then incorporate into the genome or exist as extrachromosomal DNA. DNA is generally inserted into animal cells using microinjection, where it can be injected through the cells nuclear envelope directly into the nucleus or through the use of viral vectors. In plants the DNA is generally inserted using Agrobacterium-mediated recombination or biolistics.[31]
In Agrobacterium-mediated recombination, the plasmid construct must also contain T-DNA. Agrobacterium naturally inserts DNA from a tumor-inducing plasmid into any susceptible plant that it infects, causing crown gall disease. The T-DNA region of this plasmid is responsible for insertion of the DNA. The DNA to be inserted is cloned into a binary vector that contains T-DNA and can be grown in both E. coli and Agrobacterium. Once the binary vector is constructed the plasmid is transformed into Agrobacterium containing no plasmids and plant cells are infected. The Agrobacterium naturally inserts the genetic material into the plant cells.[32]
In biolistic transformation, particles of gold or tungsten are coated with DNA and then shot into young plant cells or plant embryos. Some genetic material enters the cells and transforms them. This method can be used on plants that are not susceptible to Agrobacterium infection and also allows transformation of plant plastids.
Another transformation method for plant and animal cells is electroporation, which involves subjecting cells to an electric shock, which can make the cell membrane permeable to plasmid DNA. In some cases the electroporated cells will incorporate the DNA. Due to the associated cell and DNA damage, the transformation efficiency of biolistics and electroporation is lower than with agrobacteria and microinjection.[33]
Selection
Not all the organism's cells will be transformed with the new genetic material; typically a selectable marker is used to differentiate transformed from untransformed cells. Cells that have been successfully transformed with the DNA it will also contain the marker gene. By growing the cells in the presence of an antibiotic or chemical that selects or marks the cells expressing that gene, it is possible to separate modified from unmodified cells. Another screening method involves a DNA probe that sticks only to the inserted gene. Multiple strategies can remove the marker from the mature plant.[34]
Regeneration
As often only a single cell is transformed with genetic material the modified organism must be grown from that single cell. Bacteria consists of a single cell and reproduce clonally, so regeneration is not necessary for them. In plants this is accomplished through the use of tissue culture. Each plant species has different requirements for successful regeneration. If successful, the technique produces an adult plant that contains the transgene in every cell.
In animals it is necessary to ensure that the inserted DNA is present in embryonic stem cells. Offspring can be screened for the gene. All offspring from the first generation will be heterozygous for the inserted gene and must be inbred to produce a homozygous specimen. Jurassic Park is a result of this.
Confirmation
The finding that a recombinant organism contains the inserted genes is not usually sufficient to ensure that they will be appropriately expressed in the intended tissues. To confirm the presence of the gene, PCR, Southern hybridization and DNA sequencing are employed to determine the chromosomal location and number of gene copies.
To assess gene expression, transcription, RNA processing patterns and expression and localization of protein product(s) must usually be assessed, using methods including northern hybridization, quantitative RT-PCR, Western blot, immunofluorescence and phenotypic analysis. When appropriate, the organism's offspring are studied to confirm that the trans-gene and associated phenotype are stably inherited.
In some cases further generations must be produced and confirmed, to ensure the absence of undesirable traits in the modified organism. For hybrid products such as maize, the modified organism is crossbred with other cultivars that possess required traits.
See also
- Gene gun: a method to deliver genetic modifications to plants[35]
- Protoplast: another method to deliver genetic modifications to plants[36]
- List of genetic engineering software: software to code the genetic modifications
References
- ↑ James, Clive (2008). "Global Status of Commercialized Biotech/GM Crops:2008". ISSA Brief No. 39.
- ↑ Retroviruses and Lentiviruses as suitable gene modification delivery agents
- ↑ Clive Root (2007). Domestication. Greenwood Publishing Groups. ISBN 9780313339875.
- 1 2 Noel Kingsbury. Hybrid: The History and Science of Plant Breeding University of Chicago Press, Oct 15, 2009
- ↑ Schouten, H. J.; Jacobsen, E. (2007). "Are Mutations in Genetically Modified Plants Dangerous?". Journal of Biomedicine and Biotechnology. 2007: 1–2. doi:10.1155/2007/82612.
- ↑ D. L. Hartl; V. Orel (1992). "What Did Gregor Mendel Think He Discovered?". Genetics. 131 (2): 245–25.
- ↑ Roberts, R. J. (2005). "Classic Perspective: How restriction enzymes became the workhorses of molecular biology". Proceedings of the National Academy of Sciences. 102 (17): 5905–5908. PMC 1087929 . PMID 15840723. doi:10.1073/pnas.0500923102.
- ↑ Weiss, B.; Richardson, C. C. (1967). "Enzymatic breakage and joining of deoxyribonucleic acid, I. Repair of single-strand breaks in DNA by an enzyme system from Escherichia coli infected with T4 bacteriophage". Proceedings of the National Academy of Sciences. 57 (4): 1021–8. PMC 224649 . PMID 5340583. doi:10.1073/pnas.57.4.1021.
- ↑ Lederberg, J (1952). "Cell genetics and hereditary symbiosis". Physiological reviews. 32 (4): 403–30. PMID 13003535.
- ↑ Mandel, Morton; Higa, Akiko (1970). "Calcium-dependent bacteriophage DNA infection". Journal of Molecular Biology. 53 (1): 159–162. PMID 4922220. doi:10.1016/0022-2836(70)90051-3.
- ↑ Wirth, Reinhard; Friesenegger, Anita; Fiedlerand, Stefan (1989). "Transformation of various species of gram-negative bacteria belonging to 11 different genera by electroporation". Molecular and General Genetics MGG. 216 (1): 175–177. PMID 2659971. doi:10.1007/BF00332248.
- ↑ Nester, Eugene. "Agrobacterium: The Natural Genetic Engineer (100 Years Later)". Retrieved 14 January 2011.
- ↑ Zambryski, P.; Joos, H.; Genetello, C.; Leemans, J.; Montagu, M. V.; Schell, J. (1983). "Ti plasmid vector for the introduction of DNA into plant cells without alteration of their normal regeneration capacity". The EMBO Journal. 2 (12): 2143–2150. PMC 555426 . PMID 16453482.
- ↑ Roh JY, Choi JY, Li MS, Jin BR, Je YH (2007). "Bacillus thuringiensis as a specific, safe, and effective tool for insect pest control". J Microbiol Biotechnol. 17 (4): 547–59. PMID 18051264.
- ↑ Jerry Adler (May 2011). "The Growing Menace From Superweeds". Scientific American.
- ↑ Food and Agricultural Organisation of the United Nations. "The process of genetic modification".
- ↑ Corinne A. Michels (2002). "7". Genetic Techniques for Biological Research: A Case Study Approach. John Wiley & Sons. pp. 85–88. ISBN 0-471-89919-4.
- ↑ Alberts B, Johnson A, Lewis J, et al. (2002). "8". Isolating, Cloning, and Sequencing DNA. (4th ed.). New York: Garland Science.
- ↑ R I Kaufman; B T Nixon (1996). "Use of PCR to isolate genes encoding sigma54-dependent activators from diverse bacteria". J Bacteriol. 178 (13): 3967–3970. PMC 232662 . PMID 8682806. doi:10.1128/jb.178.13.3967-3970.1996.
- ↑ Liang, J.; Luo, Y.; Zhao, H. (2011). "Synthetic biology: Putting synthesis into biology". Wiley Interdisciplinary Reviews: Systems Biology and Medicine. 3: 7–20. doi:10.1002/wsbm.104.
- ↑ Berg, P.; Mertz, J. (2010). "Personal reflections on the origins and emergence of recombinant DNA technology". Genetics. 184 (1): 9–17. PMC 2815933 . PMID 20061565. doi:10.1534/genetics.109.112144.
- ↑ Townsend JA, Wright DA, Winfrey RJ, et al. (May 2009). "High-frequency modification of plant genes using engineered zinc-finger nucleases". Nature. 459 (7245): 442–5. Bibcode:2009Natur.459..442T. PMC 2743854 . PMID 19404258. doi:10.1038/nature07845.
- ↑ Shukla VK, Doyon Y, Miller JC, et al. (May 2009). "Precise genome modification in the crop species Zea mays using zinc-finger nucleases". Nature. 459 (7245): 437–41. Bibcode:2009Natur.459..437S. PMID 19404259. doi:10.1038/nature07992.
- ↑ Grizot S, Smith J, Daboussi F, et al. (September 2009). "Efficient targeting of a SCID gene by an engineered single-chain homing endonuclease". Nucleic Acids Res. 37 (16): 5405–19. PMC 2760784 . PMID 19584299. doi:10.1093/nar/gkp548.
- ↑ Gao H, Smith J, Yang M, et al. (January 2010). "Heritable targeted mutagenesis in maize using a designed endonuclease". Plant J. 61 (1): 176–87. PMID 19811621. doi:10.1111/j.1365-313X.2009.04041.x.
- ↑ Christian M, Cermak T, Doyle EL, et al. (July 2010). "TAL Effector Nucleases Create Targeted DNA Double-strand Breaks". Genetics. 186 (2): 757–61. PMC 2942870 . PMID 20660643. doi:10.1534/genetics.110.120717.
- ↑ Li T, Huang S, Jiang WZ, et al. (August 2010). "TAL nucleases (TALNs): hybrid proteins composed of TAL effectors and FokI DNA-cleavage domain". Nucleic Acids Res. 39 (1): 359–72. PMC 3017587 . PMID 20699274. doi:10.1093/nar/gkq704.
- ↑ S.C. Ekker (2008). "Zinc finger-based knockout punches for zebrafish genes". Zebrafish. 5 (2): 1121–3. PMC 2849655 . PMID 18554175. doi:10.1089/zeb.2008.9988.
- ↑ Geurts AM, Cost GJ, Freyvert Y, et al. (July 2009). "Knockout rats via embryo microinjection of zinc-finger nucleases". Science. 325 (5939): 433. Bibcode:2009Sci...325..433G. PMC 2831805 . PMID 19628861. doi:10.1126/science.1172447.
- ↑ Chen I, Dubnau D (2004). "DNA uptake during bacterial transformation". Nature Reviews Microbiology. 2 (3): 241–9. PMID 15083159. doi:10.1038/nrmicro844.
- ↑ Graham Head; Hull, Roger H; Tzotzos, George T. (2009). Genetically Modified Plants: Assessing Safety and Managing Risk. London: Academic Pr. p. 244. ISBN 0-12-374106-8.
- ↑ Gelvin, S. B. (2003). "Agrobacterium-Mediated Plant Transformation: the Biology behind the "Gene-Jockeying" Tool". Microbiology and Molecular Biology Reviews. 67 (1): 16–37, table of contents. PMC 150518 . PMID 12626681. doi:10.1128/MMBR.67.1.16-37.2003.
- ↑ Behrooz Darbani; Safar Farajnia; Mahmoud Toorchi; Saeed Zakerbostanabad; Shahin Noeparvar; C. Neal Stewart Jr. (2010). "DNA-Delivery Methods to Produce Transgenic Plants". Science Alert.
- ↑ Barbara Hohn; Avraham A Levy; Holger Puchta (2001). "Elimination of selection markers from transgenic plants". Current Opinion in Biotechnology. 12 (2): 139–143. PMID 11287227. doi:10.1016/S0958-1669(00)00188-9.
- ↑ Methods of genetic modification with plants
- ↑ Methods of genetic modification with plants