The 7 important molecular tools used in genetic engineering

Gene cloning is the process in which a gene of interest is located and copied  out of DNA extracted from an organism. When DNA is extracted from an organism, all of its genes are extracted at one time. This DNA, which contains thousands of different genes. An engineer is a person who constructs and manipulates according to a plan. The term genetic engineer is for an individual who is involved in genetic manipulations.They must find the one specific gene that encodes the specific protein.

The genetic engineer’s molecular tools namely the enzymes most commonly used in genetic engineering experiments are given below:

1. Polymerase Chain Reaction


The discovery of thermostable DNA polymerases, such as Taq Polymerase, made it possible to manipulate DNA replication in the laboratory and was essential to the development of PCR. Primers specific to a particular region of DNA, on either side of the gene of interest, are used, and replication is stopped and started repetitively, generating millions of copies of that gene. These copies can then be separated and purified using gel electrophoresis.

 2. Restriction Enzymes (Molecular Scissor)


The discovery of enzymes known as restriction endonucleases has been essential to protein engineering. These enzymes cut DNA at specific locations based on the nucleotide sequence. Hundreds of different restriction enzymes, capable of cutting DNA at a distinct site, have been isolated from many different strains of bacteria. DNA cut with a restriction enzyme produces many smaller fragments, of varying sizes. These can be separated using gel electrophoresis or chromatography.

 3. Electrophoresis


Purifying DNA from a cell culture, or cutting it using restriction enzymes wouldn’t be of much use if we couldn’t visualize the DNA – that is, find a way to view whether or not your extract contains anything, or what size fragments you’ve cut it into. One way to do this is by gel electrophoresis. Gels are used for a variety of purposes, from viewing cut DNA to detecting DNA inserts and knockouts.

 4. DNA Ligase


In genetic research it is often necessary to link two or more individual strands of DNA, to create a recombinant strand, or close a circular strand that has been cut with restriction enzymes. Enzymes called DNA ligases can create covalent bonds between nucleotide chains. The enzymes DNA polymerase I and polynucleotide kinase are also important in this process, for filling in gaps, or phosphorylating the 5′ ends, respectively.

5. Selection of Small Self-Replicating DNA


Small circular pieces of DNA that are not part of a bacterial genome, but are capable of self-replication, are known as plasmids. Plasmids are often used asvectors to transport genes between microorganisms. In biotechnology, once the gene of interest has been amplified and both the gene and plasmid are cut by restriction enzymes, they are ligated together generating what is known as a recombinant DNA. Viral (bacteriophage) DNA can also be used as a vector, as can cosmids, recombinant plasmids containing bacteriophage genes.

6. Method to Move a Vector into a Host Cell


The process of transferring genetic material on a vector such as a plasmid, into new host cells, is called transformation. This technique requires that the host cells are exposed to an environmental change which makes them “competent” or temporarily permeable to the vector. Electroporation is one such technique. The larger the plasmid, the lower the efficiency with which it is taken up by cells. Larger DNA segments are more easily cloned using bacteriophage, retrovirus or other viral vectors or cosmids in a method called transduction. Phage or viral vectors are often used in regenerative medicine but may cause insertion of DNA in parts of our chromosomes where we don’t want it, causing complications and even cancer.

7. Methods to Select Transgenic Organisms


Not all cells will take up DNA during transformation. It is essential that there be a method of detecting the ones that do. Generally, plasmids carry genes for antibiotic resistance and transgenic cells can be selected based on expression of those genes and their ability to grow on media containing that antibiotic. Alternative methods of selection depend on the presence of other reporter proteins such as the x-gal/lacZ system, or green fluorescence protein, which allow selection based on color and fluorescence, respectively.

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