Genetically modified bacteria

Genetically modified bacteria were the first organisms to be modified in the laboratory, due to their simple genetics.[1] These organisms are now used for several purposes, and are particularly important in producing large amounts of pure human proteins for use in medicine.[2]

Part of a series on
Genetic engineering
 
Genetically modified organisms
  • BacteriaViruses
  • Animals (Mammals • Fish • Insects)
  • Plants (Maize • Rice • Soybean)
History and regulation
  • History
  • Regulation (Substantial equivalence • Cartagena Protocol on Biosafety)
Process
Applications
  • Genetically modified crops (food)
  • Gene therapy (Designer baby)
Controversies
  • Genetically modified food controversies
  • GMO conspiracy theories
  • Pusztai affair • Séralini affair
  • StarLink corn recall
  • Lulu and Nana controversy

History

The first example of this occurred in 1978 when Herbert Boyer, working at a University of California laboratory, took a version of the human insulin gene and inserted into the bacterium Escherichia coli to produce synthetic "human" insulin. Four years later, it was approved by the U.S. Food and Drug Administration.


How genetically modified bacteria works?

Every organism has DNA, from humans down to bacteria. A gene is a small piece of that DNA. DNA is found in cells and produces proteins designed for a specific task within the organism. DNA contains the genetic information for making these proteins. DNA dictates what the organism will grow into and controls everything about an organism, from disease resistance to something as simple as nail growth. Genetic modification is the alteration, deletion, or addition of a gene for a certain outcome. The first step in genetically modifying a bacteria is finding out which chromosome contains the desired gene. Then scientists often study the gene they would like to alter and will be looking at the characteristics of the gene and how to gene reacts to different factors.[3] In bacterial modification this works by inserting a certain gene into a virus and having the virus infect the bacteria. The bacteria takes on the new gene and passes it on through prokaryotic reproduction and the offspring will also have the new gene. Eventually the original gene of the form will become obsolete or non existent because the more favorable gene will out last the other and eventually will fill the gap the other left.[4]

Research
Left: Bacteria transformed with pGLO under ambient light Right: Bacteria transformed with pGLO visualised under ultraviolet light

Bacteria were the first organisms to be genetically modified in the laboratory, due to the relative ease of modifying their chromosomes.[5] This ease made them important tools for the creation of other GMOs. Genes and other genetic information from a wide range of organisms can be added to a plasmid and inserted into bacteria for storage and modification. Bacteria are cheap, easy to grow, clonal, multiply quickly, are relatively easy to transform, and can be stored at -80 °C almost indefinitely. Once a gene is isolated it can be stored inside the bacteria, providing an unlimited supply for research.[6] The large number of custom plasmids make manipulating DNA excised from bacteria relatively easy.[7]

Their ease of use has made them great tools for scientists looking to study gene function and evolution. Most DNA manipulation takes place within bacterial plasmids before being transferred to another host. Bacteria are the simplest model organism and most of our early understanding of molecular biology comes from studying Escherichia coli.[8] Scientist can easily manipulate and combine genes within the bacteria to create novel or disrupted proteins and observe the effect this has on various molecular systems. Researchers have combined the genes from bacteria and archaea, leading to insights on how these two diverged in the past.[9] In the field of synthetic biology, they have been used to test various synthetic approaches, from synthesizing genomes to creating novel nucleotides.[10][11][12]

Food

Bacteria have been used in the production of food for a long time, and specific strains have been developed and selected for that work on an industrial scale. They can be used to produce enzymes, amino acids, flavourings, and other compounds used in food production. With the advent of genetic engineering, new genetic changes can easily be introduced into these bacteria. Most food-producing bacteria are lactic acid bacteria, and this is where the majority of research into genetically engineering food-producing bacteria has gone. The bacteria can be modified to operate more efficiently, reduce toxic byproduct production, increase output, create improved compounds, and remove unnecessary pathways.[13] Food products from genetically modified bacteria include alpha-amylase, which converts starch to simple sugars, chymosin, which clots milk protein for cheese making, and pectinesterase, which improves fruit juice clarity.[14]


In beer.

Yeast is used in beer to give it alcoholic content, also to add flavor to beer. Yeast adds over 500 tastes and aromas to beer. Yeast is being genetically modified to make the alcoholic content higher, make flavors stronger, and to make more robust flavors. There are limits to the changes brewers can make to microbes (both fungi and bacteria), currently the only changes they can make are chopping out chunks of a microbe's DNA or encouraging the microbe to create more of a gene the brewer favors. The overall goal of the brewing community is to be able to one day control the entire genome of specific brewing microbes. This would allow them to make more minor tweaks to the micobes genes. [15]

In cheese.

Chymosin is an enzyme found in a calf's stomach. This helps the calf break down the milk to digest. Chymosin is necessary in order to make cheese. It turns the milk into cheese. Scientists have found a way to alter yeast to grow Chymosin enzymes for making cheese. This process is much more efficient because previously calves had to be slaughtered in order to extract the Chymosin from the inner lining of the stomach. Also this offers a vegetarian friendly way to make cheese.[16] it depends on what and how the Bactria does the process.

Industrial

Genetically modified bacteria are used to produce large amounts of proteins for industrial use. Generally the bacteria are grown to a large volume before the gene encoding the protein is activated. The bacteria are then harvested and the desired protein purified from them.[17] The high cost of extraction and purification has meant that only high value products have been produced at an industrial scale.[18]

Pharmaceutical production

The majority of the industrial products from bacteria are human proteins for use in medicine.[19] Many of these proteins are impossible or difficult to obtain via natural methods and they are less likely to be contaminated with pathogens, making them safer.[17] Prior to recombinant protein products, several treatments were derived from cadavers or other donated body fluids and could transmit diseases.[20] Indeed, transfusion of blood products had previously led to unintentional infection of haemophiliacs with HIV or hepatitis C; similarly, treatment with human growth hormone derived from cadaver pituitary glands may have led to outbreaks of Creutzfeldt–Jakob disease.[20][21]

The first medicinal use of GM bacteria was to produce the protein insulin to treat diabetes.[22] Other medicines produced include clotting factors to treat haemophilia,[23] human growth hormone to treat various forms of dwarfism,[24][25] interferon to treat some cancers, erythropoietin for anemic patients, and tissue plasminogen activator which dissolves blood clots.[17] Outside of medicine they have been used to produce biofuels.[26] There is interest in developing an extracellular expression system within the bacteria to reduce costs and make the production of more products economical.[18]

Health

With greater understanding of the role that the micobiome plays in human health, there is the potential to treat diseases by genetically altering the bacteria to, themselves, be therapeutic agents. Ideas include altering gut bacteria so they destroy harmful bacteria, or using bacteria to replace or increase deficient enzymes or proteins. One research focus is to modify Lactobacillus, bacteria that naturally provide some protection against HIV, with genes that will further enhance this protection.[27] The bacteria which generally cause tooth decay have been engineered to no longer produce tooth-corroding lactic acid.[28] These transgenic bacteria, if allowed to colonize a person's mouth, could perhaps reduce the formation of cavities.[29] Transgenic microbes have also been used in recent research to kill or hinder tumors, and to fight Crohn's disease.[30]

If the bacteria do not form colonies inside the patient, the person must repeatedly ingest the modified bacteria in order to get the required doses. Enabling the bacteria to form a colony could provide a more long-term solution, but could also raise safety concerns as interactions between bacteria and the human body are less well understood than with traditional drugs.

One example of such an intermediate, which only forms short-term colonies in the gastrointestinal tract, may be Lactobacillus Acidophilus MPH734. This is used as a specific in the treatment of Lactose Intolerance. This genetically modified version of Lactobacillus acidophilus bacteria produces a missing enzyme called lactase which is used for the digestion of lactose found in dairy products or, more commonly, in food prepared with dairy products. The short term colony is induced over a one-week, 21-pill treatment regimen, afterwhich, the temporary colony can produce lactase for three months or more before it is removed from the body by a natural processes. The induction regimen can be repeated as often as necessary to maintain protection from the symptoms of lactose intolerance, or discontinued with no consequences, except the return of the original symptoms.

There are concerns that horizontal gene transfer to other bacteria could have unknown effects. As of 2018 there are clinical trials underway testing the efficacy and safety of these treatments.[27]

Agriculture

For over a century bacteria have been used in agriculture. Crops have been inoculated with Rhizobia (and more recently Azospirillum) to increase their production or to allow them to be grown outside their original habitat. Application of Bacillus thuringiensis (Bt) and other bacteria can help protect crops from insect infestation and plant diseases. With advances in genetic engineering, these bacteria have been manipulated for increased efficiency and expanded host range. Markers have also been added to aid in tracing the spread of the bacteria. The bacteria that naturally colonise certain crops have also been modified, in some cases to express the Bt genes responsible for pest resistance. Pseudomonas strains of bacteria cause frost damage by nucleating water into ice crystals around themselves. This led to the development of ice-minus bacteria, that have the ice-forming genes removed. When applied to crops they can compete with the ice-plus bacteria and confer some frost resistance.[31]

This artwork is made with bacteria modified to express 8 different colours of fluorescent proteins.

Other uses

Other uses for genetically modified bacteria include bioremediation, where the bacteria are used to convert pollutants into a less toxic form. Genetic engineering can increase the levels of the enzymes used to degrade a toxin or to make the bacteria more stable under environmental conditions.[32] GM bacteria have also been developed to leach copper from ore,[33] clean up mercury pollution[34] and detect arsenic in drinking water.[35] Bioart has also been created using genetically modified bacteria. In the 1980s artist Jon Davis and geneticist Dana Boyd converted the Germanic symbol for femininity (ᛉ) into binary code and then into a DNA sequence, which was then expressed in Escherichia coli.[36] This was taken a step further in 2012, when a whole book was encoded onto DNA.[37] Paintings have also been produced using bacteria transformed with fluorescent proteins.[36][38][39]

Bacteria-synthesized transgenic products

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Further reading
  • Karl Drlica (2004). Understanding DNA and Gene Cloning: A Guide for the Curious (4th ed.). ISBN 978-0-471-43416-0.
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