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I have a research paper to do about a something is classified as gentic engineering. If you have any ideas please help!

2006-10-17 13:31:05 · 4 answers · asked by kyrsten425 1 in Science & Mathematics Engineering

4 answers

ask the jehova's witnesses . they might have a lot to say against it... or try wikiedia.

2006-10-17 13:47:39 · answer #1 · answered by lnfrared Loaf 6 · 0 0

There are many definitions for genetic engineering. People disagree about what the term covers.

In the simplest usage, any engineering or controlling of the genetic make-up of a plant or animal is "genetic engineering". Farmers have been engineering the genetics of crops for thousands of years by choosing from a harvest, seeds from the plants producing biggest and best product. This careful collection through thousands of seasons drastically changed the genetic make-up of grains and other crops so that grains and fruits and vegetables are bigger and better tasting.

People have also been selectively breeding farm animals and pets for thousands of years. By deliberate breeding, farmers "engineered" specific genetic traits into the animals. We make faster horses, meatier cows, etc. We also bred a strange variety of dogs.

In recent times, new technologies have allowed for faster changing of the genetic make-up of plants and animals. In some cases significant changes can be introduced in a single generation, rather than the multi-generation timing for traditional breeding and selection methods .

2006-10-17 22:59:10 · answer #2 · answered by enginerd 6 · 0 0

Depends on what ure essay is about. Genetic enginerring is a way of scientists taking genes from one animal, plant, or organism, and inserting it into anoither animla, plant or organism, They may use many genes instead of just one. Thye use genetic enginerring for many things. For ex, strawberries are gentcially enginerred. If they werent, they would last as long, and they wouldnt b as big. They even gentically negineered a rabbit so that it glows green fluorescently.

2006-10-17 20:42:36 · answer #3 · answered by Anonymous · 0 1

Genetic engineering, genetic modification (GM) and gene splicing are terms for the process of manipulating genes, usually outside the organism's normal reproductive process.

It involves the isolation, manipulation and reintroduction of DNA into cells or model organisms, usually to express a protein. The aim is to introduce new characteristics or attributes physiologically or physically, such as making a crop resistant to a herbicide, introducing a novel trait, or producing a new protein or enzyme. Examples can include the production of human insulin through the use of modified bacteria, the production of erythropoietin in Chinese Hamster Ovary cells, and the production of new types of experimental mice such as the OncoMouse (cancer mouse) for research, through genetic redesign.

Since a protein is specified by a segment of DNA called a gene, future versions of that protein can be modified by changing the gene's underlying DNA. One way to do this is to isolate the piece of DNA containing the gene, precisely cut the gene out, and then reintroduce (splice) the gene into a different DNA segment. Daniel Nathans and Hamilton Smith received the 1978 Nobel Prize in physiology or medicine for their isolation of restriction endonucleases, which are able to cut DNA at specific sites. Together with ligase, which can join fragments of DNA together, restriction enzymes formed the initial basis of recombinant DNA technology.

Applications
The first Genetically Engineered drug was human insulin approved by the USA's FDA in 1982 [1]. Another early application of GE was to create human growth hormone as replacement for a drug that was previously extracted from human cadavers. In 1986 the FDA approved the first genetically engineered vaccine for humans, for hepatitis B[2]. Since these early uses of the technology in medicine, the use of GE has expanded to supply many drugs and vaccines.

One of the best known applications of genetic engineering is that of the creation of genetically modified organisms (GMOs).

There are potentially momentous biotechnological applications of GM, for example oral vaccines produced naturally in fruit, at very low cost.

A radical ambition of some groups is human enhancement via genetics, eventually by molecular engineering. See also: transhumanism.

DNA sequencing is a technique which is used to identify each base in DNA. Although the costs of DNA sequencing has dropped dramatically, the NIH estimates it costs at least $10 million to sequence 3 billion base pairs [3] - the size of the whole human genome.

Genetic engineering and research
Although there has been a tremendous revolution in the biological sciences in the past twenty years, there is still a great deal that remains to be discovered. The completion of the sequencing of the human genome, as well as the genomes of most agriculturally and scientifically important plants and animals, has increased the possibilities of genetic research immeasurably. Expedient and inexpensive access to comprehensive genetic data has become a reality with billions of sequenced nucleotides already online and annotated. Now that the rapid sequencing of arbitrarily large genomes has become a simple, if not trivial affair, a much greater challenge will be elucidating function of the extraordinarily complex web of interacting proteins, dubbed the proteome, that constitutes and powers all living things. Genetic engineering has become the gold standard in protein research, and major research progress has been made using a wide variety of techniques, including:

* Loss of function, such as in a knockout experiment, in which an organism is engineered to lack the activity of one or more genes. This allows the experimenter to analyze the defects caused by this mutation, and can be considerably useful in unearthing the function of a gene. It is used especially frequently in developmental biology. A knockout experiment involves the creation and manipulation of a DNA construct in vitro, which, in a simple knockout, consists of a copy of the desired gene which has been slightly altered such as to cripple its function. The construct is then taken up by embryonic stem cells, where the engineered copy of the gene replaces the organism's own gene. These stem cells are injected into blastocysts, which are implanted into surrogate mothers. Another method, useful in organisms such as Drosophila (fruit fly), is to induce mutations in a large population and then screen the progeny for the desired mutation. A similar process can be used in both plants and prokaryotes. this is all wrong so do not use this for a reports
* Gain of function experiments, the logical counterpart of knockouts. These are sometimes performed in conjunction with knockout experiments to more finely establish the function of the desired gene. The process is much the same as that in knockout engineering, except that the construct is designed to increase the function of the gene, usually by providing extra copies of the gene or inducing synthesis of the protein more frequently.
* 'Tracking' experiments, which seek to gain information about the localization and interaction of the desired protein. One way to do this is to replace the wild-type gene with a 'fusion' gene, which is a juxtaposition of the wild-type gene with a reporting element such as Green Fluorescent Protein (GFP) that will allow easy visualization of the products of the genetic modification. While this is a useful technique, the manipulation can destroy the function of the gene, creating secondary effects and possibly calling into question the results of the experiment. More sophisticated techniques are now in development that can track protein products without mitigating their function, such as the addition of small sequences which will serve as binding motifs to monoclonal antibodies.

You could get more information from the link below...

2006-10-18 07:44:19 · answer #4 · answered by catzpaw 6 · 0 0

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