- Biotechnology
Biotechnology is
technology based onbiology , especially when used inagriculture ,food science , andmedicine . TheUnited Nations Convention on Biological Diversity defines biotechnology as: [" [http://www.biodiv.org/convention/convention.shtml The Convention on Biological Diversity] (Article 2. Use of Terms)." "United Nations ." 1992. Retrieved onFebruary 6 ,2008 .]Biotechnology is often used to refer to
genetic engineering technology of the 21st century, however the term encompasses a wider range and history of procedures for modifying biological organisms according to the needs of humanity, going back to the initial modifications of native plants into improved food crops throughartificial selection and hybridization.Bioengineering is the science upon which all biotechnological applications are based. With the development of new approaches and modern techniques, traditional biotechnology industries are also acquiring new horizons enabling them to improve the quality of their products and increase the productivity of their systems.Before 1971, the term, "biotechnology", was primarily used in the
food processing andagriculture industries. Since the 1970s, it began to be used by the Western scientific establishment to refer to laboratory-based techniques being developed in biological research, such asrecombinant DNA ortissue culture -based processes, orhorizontal gene transfer in living plants, using vectors such as the "Agrobacterium " bacteria to transfer DNA into a host organism. In fact, the term should be used in a much broader sense to describe the whole range of methods, both ancient and modern, used to manipulate organic materials to reach the demands of food production. So the term could be defined as, "The application of indigenous and/or scientific knowledge to the management of (parts of) microorganisms, or of cells and tissues of higher organisms, so that these supply goods and services of use to the food industry and its consumers.Bunders, J.; Haverkort, W.; Hiemstra, W. " [http://books.google.com/books?id=rPhuRAM-WA4C&pg=PP1&ots=R0SMf5kzQQ&dq=biotechnology&sig=S8xlNTyWU_uhnn8ytC9wX9QFA_Q#PPR1,M1 Biotechnology: Building on Farmer's Knowledge] ." 1996, Macmillan Education, Ltd. ISBN 0333670825]Biotechnology combines disciplines like
genetics ,molecular biology ,biochemistry ,embryology andcell biology , which are in turn linked to practical disciplines likechemical engineering ,information technology , androbotics .Patho-biotechnology describes the exploitation of pathogens or pathogen derived compounds for beneficial effect.History
The most practical use of biotechnology, which is still present today, is the cultivation of plants to produce food suitable to humans.
Agriculture has been theorized to have become the dominant way of producing food since theNeolithic Revolution . The processes and methods of agriculture have been refined by other mechanical and biological sciences since its inception. Through early biotechnology, farmers were able to select the best suited and highest-yield crops to produce enough food to support a growing population. Other uses of biotechnology were required as crops and fields became increasingly large and difficult to maintain. Specific organisms and organism by-products were used tofertilize , restore nitrogen, and control pests. Throughout the use of agriculture, farmers have inadvertently altered the genetics of their crops through introducing them to new environments and breeding them with other plants--one of the first forms of biotechnology. Cultures such as those inMesopotamia ,Egypt , andPakistan developed the process ofbrewing beer . It is still done by the same basic method of using malted grains (containing enzymes) to convert starch from grains into sugar and then adding specific yeasts to produce beer. In this process the carbohydrates in the grains were broken down into alcohols such as ethanol. Ancient Indians also used the juices of the plant Ephedra vulgaris and used to call itSoma . Later other cultures produced the process ofLactic acid fermentation which allowed the fermentation and preservation of other forms of food. Fermentation was also used in this time period to produce leavened bread. Although the process of fermentation was not fully understood untilLouis Pasteur ’s work in 1857, it is still the first use of biotechnology to convert a food source into another form.Combinations of plants and other organisms were used as
medications in many early civilizations. Since as early as 200 BC, people began to use disabled or minute amounts of infectious agents to immunize themselves against infections. These and similar processes have been refined in modern medicine and have led to many developments such asantibiotics ,vaccines , and other methods of fighting sickness.In the early twentieth century scientists gained a greater understanding of
microbiology and explored ways of manufacturing specific products. In 1917,Chaim Weizmann first used a pure microbiological culture in an industrial process, that of manufacturingcorn starch using "Clostridium acetobutylicum " to produceacetone , which theUnited Kingdom desperately needed to manufactureexplosive s duringWorld War I .Springham, D.; Springham, G.; Moses, V.; Cape, R.E. " [http://books.google.com/books?id=9GY5DCr6LD4C&dq=biotechnology Biotechnology: The Science and the Business] ." Published 1999, Taylor & Francis. p. 1. ISBN 9057024071]The field of modern biotechnology is thought to have largely begun on
June 16 ,1980 , when theUnited States Supreme Court ruled that a genetically-modifiedmicroorganism could bepatent ed in the case of "Diamond v. Chakrabarty "." [http://caselaw.lp.findlaw.com/scripts/getcase.pl?court=us&vol=447&invol=303 Diamond v. Chakrabarty, 447 U.S. 303 (1980). No. 79-139] ." "United States Supreme Court ."June 16 ,1980 . Retrieved onMay 4 ,2007 .] Indian-born Ananda Chakrabarty, working forGeneral Electric , had developed a bacterium (derived from the "Pseudomonas " genus) capable of breaking down crude oil, which he proposed to use in treating oil spills.Revenue in the industry is expected to grow by 12.9% in 2008. Another factor influencing the biotechnology sector's success is improved intellectual property rights legislation -- and enforcement -- worldwide, as well as strengthened demand for medical and pharmaceutical products to cope with an ageing, and ailing, U.S. population. [ [http://www1.ibisworld.com/pressrelease/pressrelease.aspx?prid=115 IBISWorld ] ]
Rising demand for biofuels is expected to be good news for the biotechnology sector, with the
Department of Energy estimatingethanol usage could reduce U.S. petroleum-derived fuel consumption by up to 30% by 2030. The biotechnology sector has allowed the U.S. farming industry to rapidly increase its supply of corn and soybeans -- the main inputs into biofuels -- by developing genetically-modified seeds which are resistant to pests and drought. By boosting farm productivity, biotechnology plays a crucial role in ensuring that biofuel production targets are met. [ [http://www.bio-medicine.org/biology-technology-1/The-Recession-List---Top-10-Industries-to-Fly-and-Flop-in-2008-4076-3/ The Recession List - Top 10 Industries to Fly and Fl... (ith anincreasing share accounted for by ...) ] ]Applications
Biotechnology has applications in four major industrial areas, including health care (medical), crop production and agriculture, non food (industrial) uses of crops and other products (e.g.
biodegradable plastic s,vegetable oil ,biofuel s), and environmental uses.For example, one application of biotechnology is the directed use of
organism s for the manufacture of organic products (examples includebeer andmilk products). Another example is using naturally presentbacteria by the mining industry inbioleaching . Biotechnology is also used to recycle, treat waste, clean up sites contaminated by industrial activities (bioremediation ), and also to produce biological weapons.A series of derived terms have been coined to identify several branches of biotechnology, for example:
* Red biotechnology is applied to
medical processes. Some examples are the designing of organisms to produceantibiotic s, and the engineering of genetic cures through genomic manipulation.* Green biotechnology is biotechnology applied to
agricultural processes. An example would be the selection and domestication of plants viamicropropagation . Another example is the designing oftransgenic plant s to grow under specific environmental conditions or in the presence (or absence) of certain agricultural chemicals. One hope is that green biotechnology might produce more environmentally friendly solutions than traditional industrial agriculture. An example of this is the engineering of a plant to express apesticide , thereby eliminating the need for external application of pesticides. An example of this would be Bt corn. Whether or not green biotechnology products such as this are ultimately more environmentally friendly is a topic of considerable debate.*
White biotechnology , also known as industrial biotechnology, is biotechnology applied to industrial processes. An example is the designing of an organism to produce a useful chemical. Another example is the using ofenzymes as industrialcatalyst s to either produce valuable chemicals or destroy hazardous/polluting chemicals. White biotechnology tends to consume less in resources than traditional processes used to produce industrial goods.* Blue biotechnology is a term that has been used to describe the marine and aquatic applications of biotechnology, but its use is relatively rare.
* The investments and economic output of all of these types of applied biotechnologies form what has been described as the
bioeconomy .*
Bioinformatics is an interdisciplinary field which addresses biological problems using computational techniques, and makes the rapid organization and analysis of biological data possible. The field may also be referred to as "computational biology", and can be defined as, "conceptualizing biology in terms of molecules and then applying informatics techniques to understand and organize the information associated with these molecules, on a large scale."Gerstein, M. " [http://www.primate.or.kr/bioinformatics/Course/Yale/intro.pdf Bioinformatics Introduction] ." "Yale University ." Retrieved onMay 8 ,2007 .] Bioinformatics plays a key role in various areas, such asfunctional genomics ,structural genomics , andproteomics , and forms a key component in the biotechnology and pharmaceutical sector.Medicine
In medicine, modern biotechnology finds promising applications in such areas as
*pharmacogenomics ;
* drug production;
* genetic testing; and
*gene therapy .Pharmacogenomics
right|thumbnail|250px|DNA Microarray chip -- Some can do as many as a million blood tests at once ] Pharmacogenomics is the study of how the genetic inheritance of an individual affects his/her body’s response to drugs. It is a coined word derived from the words “pharmacology ” and “genomics”. It is hence the study of the relationship between pharmaceuticals and genetics. The vision of pharmacogenomics is to be able to design and produce drugs that are adapted to each person’s genetic makeup.U.S. Department of Energy Human Genome Program, supra note 6.]Pharmacogenomics results in the following benefits:
1. Development of tailor-made medicines. Using pharmacogenomics, pharmaceutical companies can create drugs based on the
protein s, enzymes andRNA molecules that are associated with specific genes and diseases. These tailor-made drugs promise not only to maximize therapeutic effects but also to decrease damage to nearby healthy cells.2. More accurate methods of determining appropriate drug dosages. Knowing a patient’s genetics will enable doctors to determine how well his/ her body can process and metabolize a medicine. This will maximize the value of the medicine and decrease the likelihood of overdose.
3. Improvements in the drug discovery and approval process. The discovery of potential therapies will be made easier using genome targets. Genes have been associated with numerous diseases and disorders. With modern biotechnology, these genes can be used as targets for the development of effective new therapies, which could significantly shorten the drug discovery process.
4. Better vaccines. Safer vaccines can be designed and produced by organisms transformed by means of genetic engineering. These vaccines will elicit the immune response without the attendant risks of infection. They will be inexpensive, stable, easy to store, and capable of being engineered to carry several strains of pathogen at once.
Pharmaceutical products
Most traditional pharmaceutical drugs are relatively simple molecules that have been found primarily through trial and error to treat the symptoms of a disease or illness.
Biopharmaceutical s are large biological molecules known asproteins and these usually target the underlying mechanisms and pathways of a malady (but not always, as is the case with usinginsulin to treattype 1 diabetes mellitus , as that treatment merely addresses the symptoms of the disease, not the underlying cause which isautoimmunity ); it is a relatively young industry. They can deal with targets in humans that may not be accessible with traditional medicines. A patient typically is dosed with a small molecule "via" a tablet while a large molecule is typically injected.Small molecules are manufactured by chemistry but larger molecules are created by living cells such as those found in the human body: for example, bacteria cells, yeast cells, animal or plant cells.
Modern biotechnology is often associated with the use of genetically altered
microorganism s such as "E. coli " oryeast for the production of substances like syntheticinsulin orantibiotics . It can also refer to transgenic animals ortransgenic plant s, such asBt corn . Genetically altered mammalian cells, such as Chinese Hamster Ovary (CHO) cells, are also used to manufacture certain pharmaceuticals. Another promising new biotechnology application is the development ofplant-made pharmaceuticals .Biotechnology is also commonly associated with landmark breakthroughs in new medical therapies to treat
hepatitis B ,hepatitis C ,cancers ,arthritis ,haemophilia ,bone fractures ,multiple sclerosis , andcardiovascular disorders. The biotechnology industry has also been instrumental in developing molecular diagnostic devices than can be used to define the target patient population for a given biopharmaceutical.Herceptin , for example, was the first drug approved for use with a matching diagnostic test and is used to treat breast cancer in women whose cancer cells express the proteinHER2 .Modern biotechnology can be used to manufacture existing medicines relatively easily and cheaply. The first genetically engineered products were medicines designed to treat human diseases. To cite one example, in 1978
Genentech developed synthetic humanizedinsulin by joining its gene with aplasmid vector inserted into the bacterium "Escherichia coli ". Insulin, widely used for the treatment of diabetes, was previously extracted from the pancreas of abattoir animals (cattle and/or pigs). The resulting genetically engineered bacterium enabled the production of vast quantities of synthetic human insulin at relatively low cost [W. Bains, Genetic Engineering For Almost Everybody: What Does It Do? What Will It Do? (London: Penguin Books, 1987), 99.] , although the cost savings was used to increase profits for manufacturers, not passed on to consumers or their healthcare providers. According to a 2003 study undertaken by the International Diabetes Federation (IDF) on the access to and availability of insulin in its member countries, synthetic 'human' insulin is considerably more expensive in most countries where both synthetic 'human' and animal insulin are commercially available: e.g. within European countries the average price of synthetic 'human' insulin was twice as high as the price of pork insulin [ [http://www.eatlas.idf.org/ IDF 2003; "Diabetes Atlas,: 2nd ed."; International Diabetes Federation, Brussels.] ] . Yet in its position statement, the IDF writes that "there is no overwhelming evidence to prefer one species of insulin over another" and " [modern, highly-purified] animal insulins remain a perfectly acceptable alternative [ [http://www.idf.org/home/index.cfm?node=1385 IDF March 2005; "Position Statement." International Diabetes Federation, Brussels.] ] .Modern biotechnology has evolved, making it possible to produce more easily and relatively cheaply
human growth hormone ,clotting factor s forhemophiliac s,fertility drug s,erythropoietin and other drugs.U.S. Department of State International Information Programs, “Frequently Asked Questions About Biotechnology”, USIS Online; available from http://usinfo.state.gov/ei/economic_issues/biotechnology/biotech_faq.html, accessed 13 Sept 2007. Cf. C. Feldbaum, “Some History Should Be Repeated”, 295 Science, 8 February 2002, 975.] Most drugs today are based on about 500 molecular targets. Genomic knowledge of the genes involved in diseases, disease pathways, and drug-response sites are expected to lead to the discovery of thousands more new targets.Genetic testing
Genetic testing involves the direct examination of theDNA molecule itself. A scientist scans a patient’s DNA sample for mutated sequences.There are two major types of gene tests. In the first type, a researcher may design short pieces of DNA (“probes”) whose sequences are complementary to the mutated sequences. These probes will seek their complement among the base pairs of an individual’s genome. If the mutated sequence is present in the patient’s genome, the probe will bind to it and flag the mutation. In the second type, a researcher may conduct the gene test by comparing the sequence of DNA bases in a patient’s gene to disease in healthy individuals or their progeny.
Genetic testing is now used for:
* Determining sex
* Carrier screening, or the identification of unaffected individuals who carry one copy of a gene for a disease that requires two copies for the disease to manifest
* Prenatal diagnostic screening
* Newborn screening
* Presymptomatic testing for predicting adult-onset disorders
* Presymptomatic testing for estimating the risk of developing adult-onset cancers
* Confirmational diagnosis of symptomatic individuals
* Forensic/identity testingSome genetic tests are already available, although most of them are used in developed countries. The tests currently available can detect mutations associated with rare genetic disorders like
cystic fibrosis ,sickle cell anemia , andHuntington’s disease . Recently, tests have been developed to detect mutation for a handful of more complex conditions such as breast, ovarian, and colon cancers. However, gene tests may not detect every mutation associated with a particular condition because many are as yet undiscovered, and the ones they do detect may present different risks to different people and populations.Controversial questions
Several issues have been raised regarding the use of genetic testing:
1. Absence of cure. There is still a lack of effective treatment or preventive measures for many diseases and conditions now being diagnosed or predicted using gene tests. Thus, revealing information about risk of a future disease that has no existing cure presents an ethical dilemma for medical practitioners.
2. Ownership and control of genetic information. Who will own and control genetic information, or information about genes, gene products, or inherited characteristics derived from an individual or a group of people like indigenous communities? At the macro level, there is a possibility of a genetic divide, with developing countries that do not have access to medical applications of biotechnology being deprived of benefits accruing from products derived from genes obtained from their own people. Moreover, genetic information can pose a risk for minority population groups as it can lead to group stigmatization.
At the individual level, the absence of privacy and anti-discrimination legal protections in most countries can lead to discrimination in employment or insurance or other misuse of personal genetic information. This raises questions such as whether genetic privacy is different from medical privacy. [The National Action Plan on Breast Cancer and U.S. National Institutes of Health-Department of Energy Working Group on the Ethical, Legal and Social Implications (ELSI) have issued several recommendations to prevent workplace and insurance discrimination. The highlights of these recommendations, which may be taken into account in developing legislation to prevent genetic discrimination, may be found at http://www.ornl.gov/hgmis/ elsi/legislat.html.]
3. Reproductive issues. These include the use of genetic information in reproductive decision-making and the possibility of genetically altering reproductive cells that may be passed on to future generations. For example, germline therapy forever changes the genetic make-up of an individual’s descendants. Thus, any error in technology or judgment may have far-reaching consequences. Ethical issues like designer babies and human cloning have also given rise to controversies between and among scientists and bioethicists, especially in the light of past abuses with
eugenics .4. Clinical issues. These center on the capabilities and limitations of doctors and other health-service providers, people identified with genetic conditions, and the general public in dealing with genetic information.
5. Effects on social institutions. Genetic tests reveal information about individuals and their families. Thus, test results can affect the dynamics within social institutions, particularly the family.
6. Conceptual and philosophical implications regarding human responsibility, free will vis-à-vis genetic determinism, and the concepts of health and disease.
Gene therapy
vector. A new gene is inserted into an adenovirus vector, which is used to introduce the modified
DNA into a human cell. If the treatment is successful, the new gene will make a functionalprotein .]Gene therapy may be used for treating, or even curing, genetic and acquired diseases like cancer and AIDS by using normal genes to supplement or replace defective genes or to bolster a normal function such as immunity. It can be used to target somatic (i.e., body) or germ (i.e., egg and sperm) cells. In somatic gene therapy, the genome of the recipient is changed, but this change is not passed along to the next generation. In contrast, in germline gene therapy, the egg and sperm cells of the parents are changed for the purpose of passing on the changes to their offspring.
There are basically two ways of implementing a gene therapy treatment:
1. "Ex vivo", which means “outside the body” – Cells from the patient’s blood or
bone marrow are removed and grown in the laboratory. They are then exposed to a virus carrying the desired gene. The virus enters the cells, and the desired gene becomes part of the DNA of the cells. The cells are allowed to grow in the laboratory before being returned to the patient by injection into a vein.2. "In vivo", which means “inside the body” – No cells are removed from the patient’s body. Instead, vectors are used to deliver the desired gene to cells in the patient’s body.
Currently, the use of gene therapy is limited. Somatic gene therapy is primarily at the experimental stage. Germline therapy is the subject of much discussion but it is not being actively investigated in larger animals and human beings.
As of June 2001, more than 500 clinical gene-therapy trials involving about 3,500 patients have been identified worldwide. Around 78% of these are in the United States, with Europe having 18%. These trials focus on various types of cancer, although other multigenic diseases are being studied as well. Recently, two children born with
severe combined immunodeficiency disorder (“SCID”) were reported to have been cured after being given genetically engineered cells.Gene therapy faces many obstacles before it can become a practical approach for treating disease. [Ibid] At least four of these obstacles are as follows:
1. "Gene delivery tools". Genes are inserted into the body using gene carriers called vectors. The most common vectors now are viruses, which have evolved a way of encapsulating and delivering their genes to human cells in a pathogenic manner. Scientists manipulate the genome of the virus by removing the disease-causing genes and inserting the therapeutic genes. However, while viruses are effective, they can introduce problems like toxicity, immune and inflammatory responses, and gene control and targeting issues.
2. "Limited knowledge of the functions of genes". Scientists currently know the functions of only a few genes. Hence, gene therapy can address only some genes that cause a particular disease. Worse, it is not known exactly whether genes have more than one function, which creates uncertainty as to whether replacing such genes is indeed desirable.
3. "Multigene disorders and effect of environment". Most genetic disorders involve more than one gene. Moreover, most diseases involve the interaction of several genes and the environment. For example, many people with cancer not only inherit the disease gene for the disorder, but may have also failed to inherit specific tumor suppressor genes. Diet, exercise, smoking and other environmental factors may have also contributed to their disease.
4. "High costs". Since gene therapy is relatively new and at an experimental stage, it is an expensive treatment to undertake. This explains why current studies are focused on illnesses commonly found in developed countries, where more people can afford to pay for treatment. It may take decades before developing countries can take advantage of this technology.
Human Genome Project
The
Human Genome Project is an initiative of the U.S. Department of Energy (“DOE”) that aims to generate a high-quality reference sequence for the entire human genome and identify all the human genes.The DOE and its predecessor agencies were assigned by the U.S. Congress to develop new energy resources and technologies and to pursue a deeper understanding of potential health and environmental risks posed by their production and use. In 1986, the DOE announced its Human Genome Initiative. Shortly thereafter, the DOE and National Institutes of Health developed a plan for a joint Human Genome Project (“HGP”), which officially began in 1990.
The HGP was originally planned to last 15 years. However, rapid technological advances and worldwide participation accelerated the completion date to 2003 (making it a 13 year project). Already it has enabled gene hunters to pinpoint genes associated with more than 30 disorders. [U.S. Department of Energy Human Genome Program, supra note 6]
Cloning
Cloning involves the removal of the nucleus from one cell and its placement in an unfertilized egg cell whose nucleus has either been deactivated or removed.
There are two types of cloning:
1. Reproductive cloning. After a few divisions, the egg cell is placed into a uterus where it is allowed to develop into a fetus that is genetically identical to the donor of the original nucleus.
2. Therapeutic cloning. [A number of scientists have called for the use the term “nuclear transplantation,” instead of “therapeutic cloning,” to help reduce public confusion. The term “cloning” has become synonymous with “somatic cell nuclear transfer,” a procedure that can be used for a variety of purposes, only one of which involves an intention to create a clone of an organism. They believe that the term “cloning” is best associated with the ultimate outcome or objective of the research and not the mechanism or technique used to achieve that objective. They argue that the goal of creating a nearly identical genetic copy of a human being is consistent with the term “human reproductive cloning,” but the goal of creating stem cells for regenerative medicine is not consistent with the term “therapeutic cloning.” The objective of the latter is to make tissue that is genetically compatible with that of the recipient, not to create a copy of the potential tissue recipient. Hence, “therapeutic cloning” is conceptually inaccurate. B. Vogelstein, B. Alberts, and K. Shine, “Please Don’t Call It Cloning!”, Science (15 February 2002), 1237] The egg is placed into a
Petri dish where it develops into embryonic stem cells, which have shown potentials for treating several ailments. [D. Cameron, “Stop the Cloning”, Technology Review, 23 May 2002’. Also available from http://www.techreview.com. [hereafter “Cameron”] ]In February 1997, cloning became the focus of media attention when Ian Wilmut and his colleagues at the Roslin Institute announced the successful cloning of a sheep, named Dolly, from the mammary glands of an adult female. The cloning of Dolly made it apparent to many that the techniques used to produce her could someday be used to clone human beings. [M.C. Nussbaum and C.R. Sunstein, Clones And Clones: Facts And Fantasies About Human Cloning (New York: W.W. Norton & Co., 1998), 11. However, there is wide disagreement within scientific circles whether human cloning can be successfully carried out. For instance, Dr. Rudolf Jaenisch of Whitehead Institute for Biomedical Research believes that reproductive cloning shortcuts basic biological processes, thus making normal offspring impossible to produce. In normal fertilization, the egg and sperm go through a long process of maturation. Cloning shortcuts this process by trying to reprogram the nucleus of one whole genome in minutes or hours. This results in gross physical malformations to subtle neurological disturbances. Cameron, supra note 30] This stirred a lot of controversy because of its ethical implications.
Agriculture
Improve yield from crops
Using the techniques of modern biotechnology, one or two
gene s may be transferred to a highly developed crop variety to impart a new character that would increase its yield (30). However, YEA while increases in crop yield are the most obvious applications of modern biotechnology in agriculture, it is also the most difficult one. Current genetic engineering techniques work best for effects that are controlled by a single gene. Many of the genetic characteristics associated with yield (e.g., enhanced growth) are controlled by a large number of genes, each of which has a minimal effect on the overall yield (31). There is, therefore, much scientific work to be done in this area.Reduced vulnerability of crops to environmental stresses
Crops containing genes that will enable them to withstand biotic and abiotic stresses may be developed. For example,
drought and excessively salty soil are two importantlimiting factor s in crop productivity. Biotechnologists are studying plants that can cope with these extreme conditions in the hope of finding the genes that enable them to do so and eventually transferring these genes to the more desirable crops. One of the latest developments is the identification of a plant gene,At-DBF2 , from thale cress, a tiny weed that is often used for plant research because it is very easy to grow and its genetic code is well mapped out. When this gene was inserted intotomato andtobacco cells (seeRNA interference ), the cells were able to withstand environmental stresses like salt, drought, cold and heat, far more than ordinary cells. If these preliminary results prove successful in larger trials, then At-DBF2 genes can help in engineering crops that can better withstand harsh environments (32). Researchers have also created transgenic rice plants that are resistant torice yellow mottle virus (RYMV). In Africa, this virus destroys majority of the rice crops and makes the surviving plants more susceptible to fungal infections (33).Increased nutritional qualities of food crops
Proteins in foods may be modified to increase their nutritional qualities. Proteins in legumes and cereals may be transformed to provide the amino acids needed by human beings for a balanced diet (34). A good example is the work of Professors
Ingo Potrykus andPeter Beyer on the so-calledGoldenrice (discussed below).Improved taste, texture or appearance of food
Modern biotechnology can be used to slow down the process of spoilage so that fruit can ripen longer on the plant and then be transported to the consumer with a still reasonable shelf life. This improves the taste, texture and appearance of the fruit. More importantly, it could expand the market for farmers in developing countries due to the reduction in spoilage.
The first genetically modified food product was a tomato which was transformed to delay its ripening (35). Researchers in
Indonesia ,Malaysia ,Thailand ,Philippines andVietnam are currently working on delayed-ripening papaya in collaboration with theUniversity of Nottingham andZeneca (36).Biotechnology in cheese production [ [http://www.europabio.org/documents/cheese.pdf EuropaBio - An animal friendly alternative for cheeze makers] ] : enzymes produced by micro-organisms provide an alternative to animal rennet – a cheese coagulant - and an alternative supply for cheese makers. This also eliminates possible public concerns with animal-derived material, although there is currently no plans to develop synthetic milk, thus making this argument less compelling. Enzymes offer an animal-friendly alternative to animal rennet. While providing comparable quality, they are theoretically also less expensive.
About 85 million tons of wheat flour is used every year to bake bread [ [http://www.europabio.org/documents/painbread.pdf EuropaBio - Biologically better bread] ] . By adding an enzyme called maltogenic amylase to the flour, bread stays fresher longer. Assuming that 10-15% of bread is thrown away, if it could just stay fresh another 5–7 days then 2 million tons of flour per year would be saved. That corresponds to 40% of the bread consumed in a country such as the USA. This means more bread becomes available with no increase in input. In combination with other enzymes, bread can also be made bigger, more appetizing and better in a range of ways.
Reduced dependence on fertilizers, pesticides and other agrochemicals
Most of the current commercial applications of modern biotechnology in agriculture are on reducing the dependence of farmers on
agrochemical s. For example, "Bacillus thuringiensis " (Bt) is a soil bacterium that produces a protein with insecticidal qualities. Traditionally, a fermentation process has been used to produce an insecticidal spray from these bacteria. In this form, theBt toxin occurs as an inactiveprotoxin , which requires digestion by an insect to be effective. There are several Bt toxins and each one is specific to certain target insects. Crop plants have now been engineered to contain and express the genes for Bt toxin, which they produce in its active form. When a susceptible insect ingests the transgenic crop cultivar expressing the Bt protein, it stops feeding and soon thereafter dies as a result of the Bt toxin binding to its gut wall. Bt corn is now commercially available in a number of countries to controlcorn borer (a lepidopteran insect), which is otherwise controlled by spraying (a more difficult process).Crops have also been genetically engineered to acquire tolerance to broad-spectrum
herbicide . The lack of cost-effective herbicides with broad-spectrum activity and no crop injury was a consistent limitation in crop weed management. Multiple applications of numerous herbicides were routinely used to control a wide range of weed species detrimental to agronomic crops. Weed management tended to rely on preemergence — that is, herbicide applications were sprayed in response to expected weed infestations rather than in response to actual weeds present. Mechanical cultivation and hand weeding were often necessary to control weeds not controlled by herbicide applications. The introduction of herbicide tolerant crops has the potential of reducing the number of herbicide active ingredients used forweed management , reducing the number of herbicide applications made during a season, and increasing yield due to improved weed management and less crop injury. Transgenic crops that express tolerance toglyphosate ,glufosinate andbromoxynil have been developed. These herbicides can now be sprayed on transgenic crops without inflicting damage on the crops while killing nearby weeds (37).From 1996 to 2001, herbicide tolerance was the most dominant trait introduced to commercially available transgenic crops, followed by insect resistance. In 2001, herbicide tolerance deployed in
soybean , corn andcotton accounted for 77% of the 626,000 square kilometres planted to transgenic crops; Bt crops accounted for 15%; and "stacked genes" for herbicide tolerance and insect resistance used in both cotton and corn accounted for 8% (38).Production of novel substances in crop plants
Biotechnology is being applied for novel uses other than food. For example,
oilseed can be modified to produce fatty acids fordetergent s, substitutefuel s andpetrochemical s.Fact|date=January 2008Potato es,tomato s,rice ,tobacco ,lettuce ,safflower s, and other plants have been genetically-engineered to produceinsulin Fact|date=January 2008 and certainvaccine s. If future clinical trials prove successful, the advantages ofedible vaccine s would be enormous, especially for developing countries. The transgenic plants may be grown locally and cheaply. Homegrown vaccines would also avoid logistical and economic problems posed by having to transport traditional preparations over long distances and keeping them cold while in transit. And since they are edible, they will not need syringes, which are not only an additional expense in the traditional vaccine preparations but also a source of infections if contaminated. [cite journal |journal= Proc Natl Acad Sci U S a |date=2007 |volume=104 |issue=26 |pages=10757–8 |title= Vaccines are for dinner |author= Pascual DW |doi=10.1073/pnas.0704516104 |pmid=17581867 |url=http://www.pnas.org/cgi/content/full/104/26/10757] In the case of insulin grown in transgenic plants, it is well-established that the gastrointestinal system breaks the protein down therefore this could not currently be administered as an edible protein. However, it might be produced at significantly lower cost than insulin produced in costly, bioreactors. For example, Calgary, Canada-based [http://www.sembiosys.ca/ SemBioSys Genetics, Inc.] reports that its safflower-produced insulin will reduce unit costs by over 25% or more and reduce the capital costs associated with building a commercial-scale insulin manufacturing facility by approximately over $100 million compared to traditional biomanufacturing facilities [ [http://www.sembiosys.ca/Main.aspx?id=14 SemBioSys ] ] .Criticism
There is another side to the agricultural biotechnology issue however. It includes increased
herbicide usage and resultant herbicide resistance, "super weeds," residues on and in food crops, genetic contamination of non-GM crops which hurt organic and conventional farmers, damage to wildlife fromglyphosate , etc. [ [http://www.sourcewatch.org/index.php?title=Monsanto_and_the_Roundup_Ready_Controversy Monsanto and the Roundup Ready Controversy - SourceWatch ] ] [ [http://www.sourcewatch.org/index.php?title=Monsanto Monsanto - SourceWatch ] ]Biological engineering
Biotechnological engineering or biological engineering is a branch of
engineering that focuses on biotechnologies and biological science. It includes different disciplines such asbiochemical engineering ,biomedical engineering , bio-process engineering, biosystem engineering and so on. Because of the novelty of the field, the definition of abioengineer is still undefined. However, in general it is an integrated approach of fundamentalbiological sciences and traditional engineering principles.Bioengineers are often employed to scale up bio processes from the laboratory scale to the manufacturing scale. Moreover, as with most engineers, they often deal with management, economic and legal issues. Since
patents and regulation (e.g.FDA regulation in the U.S.) are very important issues for biotech enterprises, bioengineers are often required to have knowledge related to these issues.The increasing number of biotech enterprises is likely to create a need for bioengineers in the years to come. Many universities throughout the world are now providing programs in bioengineering and biotechnology (as independent programs or specialty programs within more established engineering fields).
Bioremediation and Biodegradation
Biotechnology is being used to engineer and adapt
organisms especiallymicroorganisms in an effort to find sustainable ways to clean up contaminated environments. The elimination of a wide range of pollutants and wastes from the environment is an absolute requirement to promote a sustainable development of our society with low environmental impact. Biological processes play a major role in the removal ofcontaminant s and biotechnology is taking advantage of the astonishing catabolic versatility of microorganisms to degrade/convert such compounds. New methodological breakthroughs insequencing ,genomics ,proteomics ,bioinformatics and imaging are producing vast amounts of information. In the field of Environmental Microbiology,genome -based global studies open a new era providing unprecedented "in silico" views of metabolic and regulatory networks, as well as clues to the evolution of degradation pathways and to the molecular adaptation strategies to changing environmental conditions. Functional genomic and metagenomic approaches are increasing our understanding of the relative importance of different pathways and regulatory networks tocarbon flux in particular environments and for particular compounds and they will certainly accelerate the development ofbioremediation technologies andbiotransformation processes.cite book | author = Diaz E (editor). | title = Microbial Biodegradation: Genomics and Molecular Biology | edition = 1st ed. | publisher = Caister Academic Press | year = 2008 | url=http://www.horizonpress.com/biod | id = [http://www.horizonpress.com/biod ISBN 978-1-904455-17-2] ]Marine environments are especially vulnerable since oil spills of coastal regions and the open sea are poorly containable and mitigation is difficult. In addition to pollution through human activities, millions of tons of petroleum enter the marine environment every year from natural seepages. Despite its toxicity, a considerable fraction of petroleum oil entering marine systems is eliminated by the hydrocarbon-degrading activities of microbial communities, in particular by a remarkable recently discovered group of specialists, the so-called hydrocarbonoclastic bacteria (HCB).cite book |chapterurl=http://www.horizonpress.com/biod|author=Martins VAP et al|year=2008|chapter=Genomic Insights into Oil Biodegradation in Marine Systems|title=Microbial Biodegradation: Genomics and Molecular Biology|publisher=Caister Academic Press|id= [http://www.horizonpress.com/biod ISBN 978-1-904455-17-2] ]
Notable researchers and individuals
*
Canada :Frederick Banting ,Lap-Chee Tsui ,Tak Wah Mak ,Lorne Babiuk
*Europe :Paul Nurse ,Jacques Monod ,Francis Crick
*Finland :Leena Palotie
*Iceland :Kari Stefansson
*India :Kiran Mazumdar-Shaw (Biocon )
*Ireland :Timothy O'Brien ,Dermot P Kelleher
*Mexico :Francisco Bolívar Zapata ,Luis Herrera-Estrella
* U.S. :David Botstein ,Craig Venter ,Sydney Brenner ,Eric Lander ,Leroy Hood ,Robert Langer , James J. Collins,Roger Beachy ,Herbert Boyer ,Michael West ,Thomas Okarma ,James D. Watson ee also
*
Bioeconomics
*Biomimetics
*Biotechnology industrial park
*EuropaBio
*Genetic Engineering
*International Assessment of Agricultural Science and Technology for Development
*International Service for the Acquisition of Agri-biotech Applications
*List of biotechnology articles
*List of biotechnology companies
*List of emerging technologies
*NASDAQ Biotechnology Index
*Pharmaceutical company
*SWORD-financing
*References
Further reading
* Friedman, Y. "Building Biotechnology: Starting, Managing, and Understanding Biotechnology Companies." ISBN 978-0973467635.
* Oliver, Richard W. "The Coming Biotech Age." ISBN 0-07-135020-9.
* Powell, Walter W., Douglas R. White, Kenneth W. Koput, and Jason Owen-Smith). 2005. Network Dynamics and Field Evolution: The Growth of Interorganizational Collaboration in the Life Sciences. "American Journal of Sociology" 110(4):901-975. Viviana Zelizer Best Paper in Economic Sociology Award (2005-2006), American Sociological Association. http://www.journals.uchicago.edu/doi/abs/10.1086/421508
*External links
* [http://www.fao.org/docrep/006/y5160e/y5160e00.HTM A report on Agricultural Biotechnology] focusing on the impacts of "Green" Biotechnology with a special emphasis on economic aspects
* [http://www.eurasiabio.org/ Russian Biotechnology Organization]
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