Monday, 23 September 2013

Polyploidy: Would Sir Joseph Banks Approve?


If Sir Joseph Banks were to visit a suburban nursery today, would he appreciate the wide range of hybrid plants that have been derived from those he originally collected?
Fig. 1 - Sir Joseph Banks
(National Portrait Gallery, London)
Sir Joseph Banks (figure 1) was a wealthy naturalist whose many exploits included the exploration of the East Coast of Australia on the Endeavour in 1770. Some of the original species collected by Banks and botanist Daniel Solander included Banksia serrata, Castanospermum australe, Correa reflexia, Callistemon citrinus, various Melaleuca species, Grevillea mucronulata and the orchid Dendrobium canaliculatum ( Banks And Solander Species List). Today, some of these have become almost unrecognisable, due to continued hybridisation with related species over the years.

Why Hybridise?
Plant breeders have long recognised the improved features in various hybrid plants; these include larger flowers, fungal and pest resistance, longer flowering season, larger fruits and increased rigour. Many hybrid Australian plants are the result of crossing related species to produce varieties with the best qualities of each.

File:Banksia Giant Candles.jpg
Fig.2 - Banksia 'Giant Candles'
(Royal Botanic gardens, Melbourne)
For instance, a wide range of Grevillea hybrids have been developed to incorporate features such as prostate habit, vivid colouration and larger flower heads. The hybrid Grevillea ‘Emma Charlotte’, the result of a cross between Grevillea rosmarinifolia and Grevillea lanigera, is an illustration of this . Banksia ‘Giant Candles’ (figure 2) is another native hybrid – in this case, between Banksia ericifolia and Banksia spinulosa. This particular banksia has been deliberately selected for its larger than normal flower spikes and its showy orange-red colour.

Perhaps one of the best examples of hybridisation can be seen in the latest Kangaroo Paw (Anigozanthus) varieties. Hybrids of the more pedestrian Anigozanthus flavidus and Anigozanthus rufus, for instance, tend to combine both hardiness and showy colours in a smaller, bushier form that appeals to home gardeners.

Polyploidy Gives Hybrids Their Edge
One weakness of many Kangaroo Paw hybrids, however, is that they are sterile and consequently can only be propagated using tissue culture or other asexual methods. This also applies to countless other hybrid plants, such as commercial bananas, and is due to their polyploid genetic status. A polyploid organism is one that has 3 or more sets of chromosomes instead of the normal two. If the number of chromosome sets is uneven, production of gametes, and therefore sexual reproduction, is impossible.

Although it can arise from plant hybridisation, polyploidy can also be induced artificially using the alkaloid colchicine. Treatment with this chemical has the effect of preventing cell plate formation during cell division. As a result, chromosome pairs cannot separate and the treated cells become ‘tetraploid’; that is, they now have four sets of chromosomes instead of two. Such tetraploids, along with all polyploid species possessing even numbers of chromosomes, are, however, capable of reproducing sexually. Colchicine-induced polyploidy has produced some spectacular orchid and African violet varieties, as well as more productive wheat, maize and other crop plants.

Banks’ Probable Verdict
So what would Banks have thought about polyploid hybrids? Although he was unaware of modern genetics and would not have recognised the concept of polyploidy per se, Banks would have been aware of the prevalence of hybridisation in plant and animal breeding experiments. He had himself sponsored the improvement of British wool by introducing Spanish sheep into the country, and was also eager to introduce economic plant species such as breadfruit to new colonies. In the light of this, Banks may well have encouraged today’s artificial selection techniques if he had known of them.

Moreover, he may not have been surprised to learn that polyploidy occurs frequently in nature – George Caley, who collected plants for Banks between 1800-1810 , was in fact one of the first to identify naturally occurring hybrid varieties of Eucalypts. Indeed, around 30-70% of flowering plants are polyploid as a result of paired chromosomes originally failing to separate during meiosis, or because of the combination of distinct chromosome sets of two different species to create ‘alloploid’ varieties.

According to Fawcett, Maere and Van de Peer , these polyploid plants were probably instrumental in the evolution of higher plant species and continue to play an important role today. Banks, arguably one of the world’s greatest botanists, would no doubt agree with this view.

References
Botanic Gardens Trust, "Banks & Solander Species List", Department of Environment, Climate Change and Water NSW, nswgov.au, accessed 24/01/2010

Australian National Maritime Museum, "Joseph Banks and the Flora of the Australian East Coast", anmm.gov.au, accessed 25/01/2010

Fawcett, Maere and Van de Peer , 2009, "Plants with double genomes might have had a better chance to survive the Cretaceous–Tertiary extinction event", National Academy of Sciences, pnas.org, accessed 25/01/2010

Australian Native Plants Society, 2009, "The Kangaroo Paw Family – Cultivation", asgap.org.au, accessed 25/01/2010


Saturday, 24 August 2013

The Use of Electrophoresis in Forensic Science

Fig. 1 - Gel Electrophoresis of DNA

Electrophoresis has proved to be an invaluable tool in the analysis of crime scene evidence, especially in the area of DNA fingerprinting.

Electrophoresis involves the separation of chemicals along a solid medium in the presence of an applied potential difference. In electrophoresis, chemicals such as blood proteins, DNA or inorganic ions can be separated according to differences in their mass and/or charge. The solid medium used in electrophoresis is usually an agarose or polyacrylamide gel
Electrophoretic separation has uses in forensic science because it can be used to isolate and compare DNA, blood proteins and inorganic substances such as gunshot residues from crime scenes with suspects, victims or standard reference material.
Blood Protein Analysis Using Gel Electrophoresis
This process involves the separation of ‘marker’ proteins that are found on the surface of red blood cells. Many of these are antigens that determine particular blood groupings such as A, B, AB and O, and they can therefore be used to exclude suspects from being present at a crime scene.
Blood protein analysis has now been largely replaced by DNA fingerprinting of blood, because this latter method is much more specific. It can still serve a role as collaborative evidence, however, and has also had great relevance in past criminal cases.
DNA Analysis Using Gel and Capillary Electrophoresis
Fig. 2 - Capillary Electrophoresis
Electrophoresis is most frequently used in forensic science to produce DNA fingerprints, as illustrated in figure 1. DNA evidence from a crime scene can be compared to DNA samples from different suspects, for instance, and suspects can either be included or excluded from suspicion using the results of such tests
In gel electrophoresis, DNA strands from crime scenes, victims or suspects are applied to an agarose gel that is subjected to an electric potential. The more traditional RFLP (restriction fragment length polymorphism) profiling procedure is now being replaced by the PCR (polymerase chain reaction) method, which often involves the use of shorter DNA segments known as STRs (single tandem repeats). This method is faster and requires less DNA.
Capillary electrophoresis (figure 2), in which a fused silica capillary is used instead of a gel slab, is now being used more frequently in DNA electrophoresis. Although applying the same principles of separation as the more traditional gel slab electrophoresis, it is more rapid and has a higher resolution.
Inorganic Ion Analysis Using Capillary Electrophoresis
Capillary electrophoresis can also be used to separate and analyse anions found in explosives and poisons so that the substances used in crimes can be identified and even linked to suspects.
Anions capable of being isolated from explosive residues include azides, chlorates, chlorides, nitrates, nitrites, perchlorates, sulfates and thiocyanates, while the anions of interest in toxic chemicals are azides, cyanide, arsenates, arsenites, chromates, thiosulfates, oxalates, bromides and iodides.
Capillary electrophoresis is often also used in conjunction with ion chromatography to achieve more effective separation of ions.
Criminal Cases Where Electrophoresis Has Been Employed
Blood protein analysis was used as recently as the O.J. Simpson trial in 1995, when electrophoretic comparisons between O.J’s blood and blood from the crime scene showed they both had the factors A, ESD1 and PGM2+2-. This evidence was highly incriminating, as the probability of two samples having all these factor is just 0.44%.
O.J’s guilt was also suggested by DNA tests carried out on his blood, which revealed the probability of his being innocent was 1 in 57 billion. The main reason he wasn’t convicted was due to the seed of doubt the defence sowed in the minds of the jurors about possible interference with the evidence by the FBI.
Using the many DNA databases now available, such as CODIS, for instance, DNA samples from a crime scene can be compared with the DNA from suspects and victims related to that crime. Chester Dewayne Turner , for instance, was linked by DNA evidence to deaths in the U.S. as far back as March, 1987.
About 25% of violent crime cases in the U.S. since 1989, however, have in fact resulted in the exoneration of suspects because of DNA profiling procedures. For example, after spending 21 years in an Indiana prison for rape, DNA tests now indicate Larry Mayes was innocent. He was subsequently released in 2002. By 1996, over 108 post-conviction exonerations had in fact occurred in the USA using DNA profiling.
The anions of inorganic salts and acids are often found in gunshot and explosive residues, and also in foodstuffs that have been adulterated with poisons. Capillary electrophoresis can rapidly profile and often quantify these chemicals, and this method therefore has merit as collaborative evidence in forensic science.
Future Directions in Electrophoresis
Research is currently being undertaken in the US to develop portable microchip DNA profiling devices that can be used in the field. In this method, STR analysis of a small DNA sample can be achieved on the surface of microchips in much less time than traditional techniques. ‘Pulsed field electrophoresis’ is another innovation being investigated – here, the direction of the electric field is alternated, allowing for the separation of DNA molecules up to several million base pairs in length.
These, and other advances in electrophoretic technology, will ensure faster and more effective analysis of crime scene evidence in the years ahead.
References
Petricevic, S., 2010, "DNA Profiling in Forensic Science", nzic.org.nz, accessed 1/2/2010
Saferstein, R., 2004, "Criminalistics, an Introduction to Forensic Science", Pearson Education, New Jersey
Tissue, B.M, 2010, "Electrophoresis", The Chemistry Hypermedia Project, chem vt.edu, accessed 1/2/2010


How Successful Was Copenhagen?


How Successful Was Copenhagen?
The Copenhagen climate conference would arguably have been a total failure if it had not been for the 'Copenhagen Accord' initiated by President Obama.

The Copenhagen Accord was brokered by Barack Obama, Wen Jiabao, the Chinese premier. along with 25 other nations. Although most parties to this accord agreed that global temperatures could not rise above 2 degrees Celsius, no firm resolution to reduce emissions was achieved. The accord was effectively one of intent only and is not legally binding. Indeed, parties to the accord merely agreed to ‘take note’ of it.
The Road to Copenhagen
Initially, Copenhagen was intended to lay the basis for a legally binding carbon reduction scheme beyond 2012, when the conditions of the 1997 Kyoto Protocol are due to expire. Alternatively labelled ‘COP 15’, this conference was the 15th Conference of Parties set up by the United Nations Framework Convention on Climate Change (UNFCCC).COP 11 in Montreal, COP 12 in Nairobi, COP 13 in Bali and COP 14 in Poland involved negotiations leading up to Copenhagen, and much hope was held for the outcomes of COP 15 in these gatherings.
The ‘Bali Road Map’, for instance, which emerged from COP13, included plans to reduce deforestation, and to negotiate issues of mitigation, adaptation, technology and financing among UNFCCC countries. All nations present signed the agreement to consider these issues. Results in Poland were less optimistic; several developed nations, including Japan and Australia, rejected a further decrease in mid-term reduction goals and there was no general consensus among industrialised nations on long term emission targets.
COP14 did, however, produce practical technological and financial emission reduction strategies that could be adopted by developing countries. It was envisaged that Copenhagen would cement these goals into some sort of enforceable extension of Kyoto’s achievements.
What Were the Achievements of Kyoto?
To understand the Copenhagen agreement it must then be viewed in the light of what was achieved in Kyoto. The 1997 Kyoto Protocol involved a legally binding agreement among the 186 countries that have ratified it. It stipulates that the 39 ‘Annex 1’, or developed, countries reduce their collective greenhouse gas emissions by 5.2% (compared to 1990 levels) by 2012.
Means of achieving these reductions are permitted to be flexible and range from emissions trading schemes, ‘Joint Implementation’ (in which developed countries receive ‘emission reduction units’ for assisting transitional countries to reduce their emissions) and the ‘Clean Development Mechanism’, where developed countries receive credits for financing emission reduction projects in poorer nations.
Non Annex 1 countries- the so-called ‘developing nations’, were given no legally binding emission reduction targets but were given incentives to develop carbon reduction projects in exchange for carbon credits.
Enforcement of the Kyoto Protocol
The above reductions are enforceable as a result of the Marrakesh Accords, which developed a compliance system for Kyoto. Delegates from the Kyoto enforcement committee are permitted to enforce sanctions against Annex 1 countries that do not meet their emission targets or who fail to regularly submit emission updates. Countries that exceed their emissions targets will be required to make up the difference as soon as possible in addition to reducing emissions by another 30%. They will also be temporarily excluded from emissions trading schemes.
But how enforceable are these emission targets in reality? Ulfstein and Werksman point out that some of the chosen deterrents in the Kyoto protocol, such as increasing emission targets by 30% for infringing parties, may not be as effective as has been predicted. Moreover, Halvorssen and Hovi have stated that ‘ A country that deliberately fails to abide by other legally binding commitments under the Kyoto Protocol is also likely to resist the application of punitive consequences, regardless of whether these consequences are made legally binding or not.’
Outcomes of Copenhagen
In the light of this, the fact that Copenhagen achieved nothing legally binding may not be of consequence. What may be more important is the involvement of the United States, previously notorious for its non ratification of Kyoto, and the intentions agreed to. Some of these include the establishment of the ‘Copenhagen Green Carbon Fund’, which pledges 30 million dollars in the next three years, with a planned 100 billion per year by 2020 to vulnerable developing nations to help mitigate and adapt to the effects of climate change.
Another major consensus was that global temperatures should not increase by more than 2 degrees, and that the Accord should be reviewed by 2015 to discuss whether 1.5 degrees would be a better target. In addition, developing nations have agreed to submit reports of their efforts to reduce greenhouse gas emission every two years.
Nevertheless, many parties to the conference have left dissatisfied, and for various reasons. Vulnerable low lying nations such as the Cook Islands, Barbados and Fiji wanted no less than a legally binding agreement for a 1.5 degree increase in global temperatures signed both by Annex 1 and developing nations. India and China, on the other hand, wanted to continue the conditions of Kyoto so that they would remain, as non Annex 1 countries, excepted from binding emissions targets. The African group of nations walked out of talks at one stage because they could not see India, China and the U.S., all major emitters, agreeing to any binding targets.
Perhaps, then, the world needs to wait to see what the consequences of the Copenhagen Accord will be. This may happen as soon as the climate talks in Mexico later this year.
References
Copenhagen Climate Council, 2009, ‘What is the Kyoto Protocol’?, copenhagenclimatecouncil.com
Halvorssen, H., and Hovi, J., 2006,’The Nature, Origin and Impact of Legally Binding Consequences: the Case of the Climate Regime’, Springer Netherlands,Springerlink.com , accessed 6/2/2010
The German Marshall Fund of the United States, 2009, ‘Clinging to Kyoto’,gmfus.org, accessed 7/2/2010
Ulfstein, G and Werksman, J., The Kyoto Compliance System: Towards Hard Enforcement, folk.uio.no, accessed 8/2/2010
Vidal, Stratton, Goldenberg, 2009,’Low targets, goals dropped: Copenhagen ends in failure’, guardian.co.uk, accessed 6/6/2010

Monoclonal Antibodies

Fig. 1 - Mouse Cholera Antibody

Monoclonal antibodies are showing enormous potential as biological tools in the diagnosis and treatment of human disease.

Monoclonal antibodies (MAbs) are immunoglobulin proteins made to target potentially any molecule capable of instigating the production of antibodies. Such molecules are known as antigens. The antigen of concern is injected into mice, where white blood cells known as B cells produce antibodies against it (see figure 1).
The antibody -producing B cells are then hybridised with myeloma tumour cells to form ‘hybridoma’ cells, which multiply quickly, producing clones of themselves and, in turn, vast amounts of antibodies. The term ‘monoclonal’ is derived from the fact that they are produced from one type of cell- the hybridoma cell. This revolutionary procedure was developed by Kohler and Milstein, who were awarded a Nobel Prize for their work in 1984.

Because antibodies are specific for their target antigen only, MAbs have the potential to be more efficient than other drugs, which may also attack normal body cells. As a result, side effects of therapy such as nausea or allergic reactions are reduced.
Monoclonal Antibodies in Human Therapy
Monoclonal antibodies have several uses; the most obvious one being to fight the specific antigen they were produced from. One such example is Mylotarg, a drug derived from a MAb which binds to CD33, a cell-surface molecule expressed by the cancerous cells in acute myelogenous leukemia . Other MAbs approved by the FDA attack tumor cells in lymphomas and some breast cancers, while some target receptor cells on the cancerous white blood cells in chronic lymphocytic leukemia.
The immune system can also be suppressed using monoclonal antibodies; one example is Muromonab-CD3, which binds to the CD3 molecule on the surface of T cells. This acts to prevent the acute rejection of organs after transplant operations.
Despite the moderate success of these and other monoclonal treatments, progress in human therapy has been relatively slow because the human immune system naturally rejects antibodies that have originated in mice. As a result, the antibodies are usually comparatively short lived and have limited success rates. Additional drawbacks can include side effects such as vomiting and fever.
Newer therapies are consequently employing genetically engineered antibodies that combine the antigen binding properties of the mouse antibody with genetic material from human antibodies. This technique aims to reduce rejection to a manageable level. Examples of FDA approved human or chimeric MAbs include Synagis, Herceptin and Remicade,used in the treatment of breast cancer, leukaemia and rheumatoid arthritis respectively.
Monoclonals as Diagnostic Tools
The specificity of MAbs for the antigen that stimulates their production also makes them useful in the detection of these antigens in the body. This has been utilised in the identification of ABO blood groups in human serum and in the diagnosis of pregnancy-related hormones such as HCG in pregnancy testing kits.
Other diagnostic tests include the detection of drug levels, infectious diseases such as AIDS (using the ELISA test), tumour antigens and specific hormones in the human body. While many of these tests employ the use of immunoassay procedures, which quantify the formation of antigen antibody complex (Ag-Ab complex), others involve the attachment of MAbs to radioactive atoms in a process known as radioimmunodetection. In some situations fluorescent molecules or metal atoms such as copper and gold (see figure 2) may also be coupled to the antibody to assist in imaging the target.
Ethical Issues associated with MAbs
The use of mice to produce MAbs has been controversial because of the painful and debilitating effects of the procedure. In order to achieve an enhanced inflammatory immune response in the mouse, for instance, substances called adjuvants are used. These release the antigen into the mouse over a long period of time, which often results in painful lesions at the site of injection. Freund's Complete Adjuvant (FCA) has actually been banned in the Netherlands and the United Kingdom.
This, and the fact that when the required immune response has been achieved, the mouse’s spleen is removed to provide a source of antibody producing cells, has resulted in some European countries legislating to limit MAb production in mice. Alternatives being investigated include the use of tissue culture and DNA technology to produce the antibodies in vitro.
The Future of Monoclonal Antibodies
With anti-rejection technology improving continually, monoclonal antibodies may soon be extended to the therapeutic treatment of diseases outside the traditional areas of oncology, autoimmune and inflammatory disorders, such as infectious diseases and opthamology. With sales exceeding 32 billion dollars in 2008, MAbs are set to become an important sector of the pharmaceutical industry.
References
Kimball, J., 2010, `"Monoclonal Antibodies," Kimball’s Biology Pages, jkimball.ma.ultranet, accessed 23/2/2010
Lynette A. Hart, 1996, "Monoclonal antibodies," Mouse in Science,ucdavis.edu, accessed 23/2/2010
"Uses of Monoclonal Antibodies," Molecular-Plant-Biotechnology.info, accessed 25/2/2010
Washington, D.C.: Biotechnology Industry Organization, 1989, "Monoclonal Antibody Technology - The Basics," accessexcellence.org, accessed 25/2/2010

Thursday, 4 July 2013

Pharmaceuticals and Genetically Modified Algae



Fig.1 - Scanning E.M. Image of Chlamydomonas

A tiny green alga is showing promise in the production of genetically modified (GM) pharmaceuticals such as monoclonal antibodies, interleukins and nerve growth hormones.

Chlamydomonas reinhardtii (figure 1) is currently the most favoured single celled alga for the expression of human genes. There are a number of reasons for this. Firstly, its genome has been sequenced and it has been cultured successfully in laboratories for many years. The alga can in fact be grown on a simple medium of salts in the presence of light, where it can photosynthesise to produce glucose for itself. It can also be grown on an acetate medium in the absence of light, and can be economically cultured on a small or large scale (up to 500 000 litres).

Another reason for its popularity in scientific work is that the DNA of its chloroplasts, mitochondria and nucleus can be easily modified genetically. In other words, human genes (sections of DNA) can be introduced into these structures using genetic engineering techniques.
One such technique is microinjection, in which a microscopic needle inserts the desired gene into the nucleus or other cellular organelles. Another method, electroporation (figure 2), allows the introduction of foreign DNA into membranes by exposing them to a high electric potential difference. This acts to increase their permeability.
Fig.2 - Electroporator with Cuvette Loaded

Problems Associated With Protein Expression
There are difficulties posed by GM algal technology, however. In terms of nuclear expression of transgenes, for instance, allowance has to be made for ‘codon bias’; the disproportionately high GC (guanine - cytosine) level that occurs in the Chlamydomonas genome. This results in synthesised human genes which have been modified to adapt to this bias.
As Professor Joe Cummins, 2005, points out, the human immune system may reject pharmaceuticals derived from such DNA and 
therefore ‘synthetic human DNA in the alga should not be deemed equivalent until it has been tested for untoward effects on humans and the environmental biota.’ 
Proteins expressed by Chlamydomonas may in some cases undergo post translational modification to more effectively emulate the behaviour of the original human protein, unlike other GM organisms such as yeasts. Indeed, yeasts and bacteria are often incapable of fully expressing monoclonal antibodies (immunoglobulin proteins) or more complex proteins.In addition, processes not as yet fully explained within the Chlamydomonas nucleus tend to silence foreign gene expression. Several genes thought to be responsible for this phenomenon have, however, been identified and are being investigated.
With respect to expression of transgenes by the chloroplast, codon bias (this time in terms of high AT levels) also presents a problem, as does the low level of translation of foreign genes within this organelle. Recent studies, however, have shown that the Chlamydomonas chloroplast is capable of expressing complex monoclonal antibodies such as the anti- Herpes simplex antibody, HSV8lsc. Given the low cost of cultivating Chlamydomonas reinhardtii, the potential thus exists to produce this antibody on a large scale in the near future.
Environmental and Health Concerns
Proposals for such extensive cultivation in Hawaii in 2005, however, met with a vociferous backlash from scientists and community members alike. A permit granted to Mera Pharmaceuticals to establish the wide scale production of GM antibodies in large outdoor bioreactors in Kona, was contested on the basis of the risk of horizontal gene transfer through the soil and waterways. It was argued that the outdoor cultivation of Chlamydomonas could result in the alga transferring its transgenes to related soil and aquatic algae and bacteria.
Indeed, the very success of transgene expression by modified chloroplasts is itself a risk because the high level of GM proteins (including antibiotic resistant marker proteins) and foreign DNA produced increases the chances of horizontal contamination of related species. Ho and Cummins (2005), stress that the similarity between chloroplast and bacterial genomes further adds to this risk - at least 87 easily transformable bacterial soil species may be vulnerable if GM Chlamydomonas cultures are not effectively contained.
Once the above issues are explored the future of GM pharmaceuticals from these microalgae looks promising.
References
Cummins, J., 2005, Human Gene Products in the Micro Alga Chlamydomonas reinhardtii, i-sis.org, accessed 10/3/2010
Cummins, J. and Ho, M.,2005, ‘GM Pharmaceuticals From Common Algae’ ibiblio.org, accessed 9/3/2010
Franklin, S. and Mayfield, S., 2004, Prospects For Molecular Farming in the Green Alga Chlamydomonas reinhardtii, Current Opinion in Plant Biology, sciencedirect.com, accessed 9/3/2010




Saturday, 8 June 2013

What is a Transgenic Species?

Fig.1 - Crown Gall

A transgenic species is an organism that has had part of another organism's DNA (often known as a 'transgene') transferred into it using recombinant DNA technology.

The resulting organism is often known as a genetically modified organism (GMO). Examples include transgenic crops that have had genes inserted into them to improve features such as resistance to insects or disease, shelf life or nutritional value, and genetically modified bacteria which can produce human proteins on a large scale.
Other uses for GMOs include medical research and the manufacture of pharmaceuticals. In the pharmaceutical industry, GMOs such as goats, rabbits, pigs and bacteria can be used to manufacture insulin, vaccines, growth hormones, human protein C, anticoagulant and haemoglobin.
Inserting Genes Into Bacteria
Bacteria can be transformed when plasmids (loops of bacterial DNA) containing the desired gene are introduced into them. The genes on the plasmid are then expressed, and can be passed on to all subsequent bacterial generations.This process begins by using a specific restriction enzyme to remove the desired gene from human DNA. The same enzyme is then used to cut a bacterial plasmid in one place. The human gene is inserted into the gap in the plasmid, and an enzyme called DNA ligase then re-joins the 'sticky' ends that were formed by the restriction enzyme.
The recombinant plasmid is then introduced into a bacterial cell in the presence of cold calcium chloride, which makes the cell walls of the bacterium more porous. Exposure to an an electric potential difference, also known as ‘electroporation’, may also be used to successfully introduce the plasmid into the host cell. Recombinant bacteria are currently used to produce large amounts of human insulin and human growth hormone for pharmaceutical use.
Inserting Genes Into Animals
DNA microinjection is the most widely used transgenesis method in animals and involves the microinjection of a gene into the nucleus of a fertilised ovum. This is a random process and may not always lead to expression of the desired gene. As a result, transgenic animals are mated to ensure that their offspring acquire the transgene.
Embryonic stem cell-mediated gene transfer is another method used to introduce genes into animal cells. Here, the modified DNA is incorporated into embryonic stem cells of the chosen animal. These stem cells are then introduced into an embryo, resulting in a chimeric organism (that is, one where only some cells contain the desired gene).
Retrovirus mediated gene transfer is also used in some instances. Retroviruses, viruses capable of inserting their genetic material into a host cell, are modified to transfer the desired gene into the animal. Not all cells of the animal will have the gene incorporated into them, so the animal will again be chimeric. The transgene will only be genetically transmitted if the retrovirus invades the animal's sex cells. Alternatively, chimeric animals are inbred for up to 20 generations until the desired gene is present in every cell.
Transgenic animals currently being researched include transgenic cattle, sheep and pigs that can produce milk that contains human insulin, human collagen, human fertility hormones and monoclonal antibodies.
Inserting Genes Into Plants
Agrobacterium tumefaciens (crown gall bacteria) is often used as a vector to carry the desired transgene into plant cells, as its normal infection process involves inserting a circular DNA plasmid into the host cell. The plasmid is initially modified by cutting it in two places with a restriction enzyme and inserting the desired gene. It is then incorporated into the targeted plant cell via the crown gall bacteria (see fig. 1) or is introduced manually.
Examples of GM plants produced using this method include Bt cotton (fig.2), which has had a gene inserted into it to make it toxic to pests such as bollworms, and GM soybeans, which incorporate a gene from the Salmonella bacterium to make them resistant to 'roundup' insecticide.
Fig.2 - BT Cotton
Most crop plants, including the cereals and grasses, are monocotyledonous: that is, their leaves have parallel veins and they don't have a tap root system. Inserting genes into this type of plant can prove to be more difficult than with higher plants.Transgenic monocotyledons can instead be produced using a particle gun. This fires a gold bullet, coated with the desired DNA, into the nucleus of the target plant. Examples of GM monocotyledonous crops include herbicide resistant GM Canola (rapeseed), corn and sugar cane, and insect resistant Bt corn.
Ethical and Environmental Concerns Linked to GMOs
One concern associated with GM plants and animals has always been the risk of horizontal gene transfer; that is, the transgene may become incorporated into related, or even unrelated species. Herbicide resistance could, for example, spread to weeds growing alongside GM Canola with the result that they can no longer be eradicated by farmers.
Transgenic organisms may also escape to the wild and compete with native species for resources - the superior 'Sumo Salmon', a transgenic fish containing the gene for human growth hormone, is an example of this. In addition, social inequity could result from the use of GMOs. For instance, large corporations may end up owning the rights to the most productive crops, so restricting access to those most in need of them.
Thorough testing of GM0s and their products is also needed to avoid any risk to public health - the need for this was recently highlighted by a study linking Monsanto's GM corn to organ damage in rats.
Despite these concerns, the use of transgenic species in agriculture, medicine and the pharmaceutical industry has already revolutionised our lives in countless ways.
References
Goldstein, K, 2010, ‘Monsanto’s GMO Corn Linked to Organ Failure, Study Reveals’, Huffington Post, huffingtonpost.com, accessed 21/3/2010
Jigar Nare, S, 2008, 'Transgenic Animals- A Boon by Biotechnology', pharmainfo.net, accessed 23/3/2010
Pighin, J, 2003, 'Transgenic Crops: How Genetics is Providing New Ways to Envision Agriculture', scq.ubc.ca, accessed 21/3/2010