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Genetic Engineering Topics For Essays 6th

Ultrasound of a fetus in the fourth month of pregnancy. (iStock)

Each week, In Theory takes on a big idea in the news and explores it from a range of perspectives. This week, we’re talking about human genetic engineering.

George Church is professor of genetics at Harvard Medical School and stakeholder in various human genetics companies, including Veritas, Editas and Intellia. His laboratory was the first to edit DNA with CRISPR in human stem cells.

Major policy decisions are often impacted by gut feelings. One of the more exceptional technologies affected by public emotion has been genetic modification. Genetically modified “golden rice,” for example, emerged in 2002 as a potential global health solution to a vitamin A deficiency that kills a million people each year, but vandalism of field trials has contributed to the delay of rice research, which already faces technical obstacles.

[Other perspectives: Why are we telling scientists to destroy human life?]

The communication between emotions and facts is even more crucial as we begin to discuss human genetic engineering as a tool for disease treatment. It is urgent that citizens around the world inform themselves and participate in this rapidly moving set of decisions. What we decide will change all our lives, and there are a few important questions to consider:

1. Can embryos consent? There are more than 2,000 gene therapy human clinical trials in progress. Some must happen at early stages of growth — during child development, for example, to cure blindness. But early interventions, such as with fetal surgeries and medicines, involve risk without consent of the child, so the benefits for the child and society must also be considered. Ironically, doing nothing can entail the biggest risks. For example, delaying retinal gene therapy can result in children who can see light patterns but never learn to interpret faces.

2. Will genetic engineering permanently change our society? Gene therapies are typically done to cure individuals, not alter subsequent generations. But for each such therapy, if effective, the genetic changes will nevertheless be present in future children due to widespread use. This is cultural, not genetic, inheritance — as occurs with other compelling technological innovations, such as cars and phones. Indeed, “cultural inheritance” can spread far more rapidly, in a matter of months rather than over a period of 25 years in generational time. Gene therapies developed to prevent cognitive decline at age 60, for example, could be found to enhance certain skills on Wall Street at age 20 and could enter common use within years.

3. Where do we draw the line? Going forward, developing ethical and policy boundaries on genetic engineering will demand nuance. The lines around our current genetic engineering practices should not be based on categories of technology (genetic therapy vs. genetic counseling, for example), because most categories can contain both good and bad outcomes. Instead, the lines should be drawn based on the outcomes themselves and safety and efficacy, as they are for all new technologies. We should also design our policies to take into account more factors than just the severity of the disorder a genetic treatment attempts to address. If our medical industry approved treatments based on severity alone, we would be missing out on a variety of valuable treatments for seemingly simple maladies such as headaches, sleepiness, insomnia, acne and allergies.

4. Can we reduce risk to embryos? Parents who carry the genetic variation for certain serious inherited diseases (like Tay Sachs) but are themselves unaffected are currently able to avoid passing on the disease to their children by using prenatal testing during pregnancy (or more rarely in vitro “pre-implantation”). This, however, risks the abortion of embryos inherent in the choosing process, which is unacceptable to many parents. An alternative could be to edit sperm-producing cells in the father so that only non-carrier sperm are produced, eliminating the possibility of the disease showing up in embryos. Half of the children will still be carriers – due to the genes being passed on from the mother, so this would not affect the gene pool.

5. Will there be genetic consequences further down the line? The error rate of well-designed CRISPR technology is much lower than normal mutation rates in unmodified DNA, and inspecting modified sperm stem cells can reduce this rate an additional million-fold. But even if genetic effects are initially undetectable, environmental and/or social effects may become evident after many generations. We already monitor many modern discoveries for long-term effects, and tools such as CRISPR should not be an exception. As soon as we discover harm that outweighs benefit, we try to fix it. Yet cars still kill millions of people worldwide each year. Cigarettes were initially approved by health experts and sold in the trillions between 1930 and 2000, ditto for BPA from 1957 to 2008 and DDT from 1940 to 1962. More recently, the painkiller Vioxx was banned after it was shown to cause heart attacks and strokes — but only after 80 million people used it.

6. Will it exacerbate wealth inequality? Commentators have long suggested that genetic engineering will be available only to those who can afford it, resulting in wealth disparities and allowing its advantages to accrue only to a small percentage of society. This risk can be reduced by distributing the high cost of the technology’s development throughout society, as the Orphan Drug Act of 1983, passed to incentivize the development of drugs for rare diseases, meant to accomplish. The cost may also fall on its own, as has happened with electronic technology and genome sequencing. It’s also noteworthy that CRISPR and gene drive technology may provide a path to eliminating malaria or nematode diseases — saving millions of lives per year and breaking cycles of disease, poverty and illiteracy.

7. Are some traits just too complex? Not necessarily. Usually even when studies of complex genetic traits do not reveal single gene variants with large impacts in the body, they can be found via rare natural variants or synthetic biology. Indeed, the most successful therapies target a single gene product in the midst of a complex set of genetic and environmental factors. For example, while hundreds of common genetic variants add tiny effects on height, one gene product (growth hormone) outweighs all of those and is used medically. Similarly, single gene variants have been shown to significantly enhance cognitive tasks in animals. These are being tested for Alzheimer’s disease therapies. As with other therapies, side effects — if any — can be explored and fixed.

8. Are we seeking the ideal human? If so, the idea makes as little sense as seeking out “the ideal transportation”: how do we decide among jets, cars and oil tankers? Lessons of history and evolution show we need diversity, and not just in skin melanin densities. We need immunological, metabolic, cultural and mental diversity — including people with high-functioning autism, obsessive-compulsive disorder, attention deficit hyperactivity disorder, bipolar disorder, dyslexia and narcolepsy. I have mild forms of some of these “disorders” and feel we are not ready to lose them. If you’re in need of convincing, just Google each of those six pejorative terms along with “successful” or “famous.” Indeed, the Israeli military elite unit 9900 embraces autistic skills at interpreting aerial photographs. To prevent such loss, and to adapt to the world of the future, we need public support for such neural diversity. Physics and chemistry have led to leaps in the diversity of our cultural artifacts. Genetics can too.

Explore these other perspectives:

Robert Gebelhoff: What’s the difference between genetic engineering and eugenics?

Jacob Corn: CRISPR will change lives, but not only through genetic engineering

Brendan P. Foht: Why are we telling scientists to destroy human life?

Genetic engineering is the process by which an organism’s genetic material is altered or selected so that the organism will have specific characteristics.

Genetic Engineering Examples

  • Cloning - One of the most controversial uses of genetic engineering has been cloning, or producing a genetically identical copy of an organism. While the ethics of cloning are hotly debated, the first ever sheep (named Dolly) was cloned in 1996 by scientists. 
  • Glow-in-the-dark cats - It sounds strange, but in 2007, scientists in South Korea altered the DNA of a kitty so that its fur would glow in the dark, and then cloned other cats from it, making the world’s first glowing cats. 
  • Pesticide-resistant rapeseed plants - Rapeseed is a flowering plant used to make certain types of vegetable oil. Genetic engineering has allowed these plants to be resistant to certain types of pesticides, so that when the fields are treated to remove pests, the plants will remain unscathed.
  • Cows that pass less gas - Methane is produced by cow flatulence, and the chemical is a huge contributor to global warming. Cows that fart less than average have been produced to fight the deleterious effects that cow flatulence can have on the environment.
  • Plants that fight pollution - Poplar trees developed by scientists at the University of Washington can absorb polluted water through their roots and clean it before the water is released back into the air. The plants were many times more efficient at cleaning certain pollutants than regular poplars.
  • Golden rice - Genetic modification is often used to make "healthier" foods, such as golden rice, which contains beta-carotene – the very same vitamin that makes carrots orange. The result is that people without access to many vitamins will get a healthy dose of vitamin A when the rice is consumed.
  • Environmentally friendly pigs - Genetic modification has helped to create pigs that can digest phosphorous better, which decreases the pig’s phosphorous output. The result is that manure, which is often made from pig waste, is less destructive to the environment due to its lower phosphorous content.
  • Faster-growing trees - Demand for wood can be met by trees that grow faster than average. Genetic engineering has produced trees that can ward off biological attacks, grow more quickly and strongly, and create better wood than trees that are not genetically modified.
  • Bigger, longer-lasting tomatoes - When tomatoes are genetically engineered, they can be made bigger and more robust. These are engineered to produce tomatoes that can remain fresh for longer, can be shipped farther from where they are grown, and can be harvested all at the same time rather than harvesting only parts of a field at each harvest.
  • Salmon that grow faster - Salmon do not produce growth hormones year-round, so scientists have looked toward genetic engineering and found a solution: a modification that allows salmon to grow twice as fast than those that are not engineered.
  • Insecticide corn - Instead of spraying insecticide on plants, why not genetically engineer crops that kill pests on their own? Corn was developed through genetic engineering to produce a poison that kills insects. While this corn may also harm beneficial insects such as butterflies, supporters say that the pros outweigh the cons.
  • The banana vaccine - Bananas were developed through genetic modification that offer vaccine against diseases such as cholera and hepatitis. Just like with a needle vaccine, people who eat them develop disease-combating antibodies that make them immune to a disease.

As some of these examples show, genetic engineering can be a controversial science; but, it may also serve many useful purposes. 

Do you have a good example to share? Add your example here.

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Examples of Genetic Engineering

By YourDictionary

Genetic engineering is the process by which an organism’s genetic material is altered or selected so that the organism will have specific characteristics.

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