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Scientists Release Controversial Genetically Modified Mosquitoes In High-Security Lab (npr.org)
An anonymous reader quotes a report from NPR: Scientists have launched a major new phase in the testing of a controversial genetically modified organism: a mosquito designed to quickly spread a genetic mutation lethal to its own species, NPR has learned. For the first time, researchers have begun large-scale releases of the engineered insects, into a high-security laboratory in Terni, Italy. The goal is to see if the mosquitoes could eventually provide a powerful new weapon to help eradicate malaria in Africa, where most cases occur. The lab was specially built to evaluate the modified insects in as close to a natural environment as possible without the risk of releasing them into the wild, about which there are deep concerns regarding unforeseen effects on the environment.
To prevent any unforeseen effects on the environment, scientists have always tried to keep genetically engineered organisms from spreading their mutations. But in this case, researchers want the modification to spread. So they engineered mosquitoes with a "gene drive." A gene drive is like a "selfish gene," says entomologist Ruth Mueller, because it doesn't follow the normal rules of genetics. Normally, traits are passed to only half of all offspring. With the gene drive, nearly all the progeny inherit the modification. Researchers created the mosquitoes by using the powerful new gene-editing technique known as CRISPR, which Mueller likens to a "molecular scissor which can cut at a specific site in the DNA." The cut altered a gene known as "doublesex," which is involved in the sexual development of the mosquitoes. While genetically female, the transformed insects have mouths that resemble male mosquito mouths. That means they can't bite and so can't spread the malaria parasite. In addition, the insects' reproductive organs are deformed, which means they can't lay eggs. As more and more female mosquitoes inherit two copies of the modification, more and more become sterile. Critics fear that these gene-drive mosquitoes could run amok and wreak havoc in the wild. Not only could the insects cause a negative effect on crops by eliminating important pollinators, but the insects' population crash could also lead to other mosquitos coming with other diseases.
Mueller assures NPR's Rob Stein that the lab the mosquitos are in is very secure, adding that even if the mosquitos did escape they would not be able to survive Italy's climate. "To enter the most secure part of the facility, Mueller punches a security code into a keypad to open a sliding glass door," reports NPR. "As the door seals, a powerful blower makes sure none of the genetically modified mosquitoes inside escape. Anyone entering must don white lab coats to make it easier to spot any mosquitoes that might try to hitch a ride out of the lab and must pass through a second sealed door and blower."
To prevent any unforeseen effects on the environment, scientists have always tried to keep genetically engineered organisms from spreading their mutations. But in this case, researchers want the modification to spread. So they engineered mosquitoes with a "gene drive." A gene drive is like a "selfish gene," says entomologist Ruth Mueller, because it doesn't follow the normal rules of genetics. Normally, traits are passed to only half of all offspring. With the gene drive, nearly all the progeny inherit the modification. Researchers created the mosquitoes by using the powerful new gene-editing technique known as CRISPR, which Mueller likens to a "molecular scissor which can cut at a specific site in the DNA." The cut altered a gene known as "doublesex," which is involved in the sexual development of the mosquitoes. While genetically female, the transformed insects have mouths that resemble male mosquito mouths. That means they can't bite and so can't spread the malaria parasite. In addition, the insects' reproductive organs are deformed, which means they can't lay eggs. As more and more female mosquitoes inherit two copies of the modification, more and more become sterile. Critics fear that these gene-drive mosquitoes could run amok and wreak havoc in the wild. Not only could the insects cause a negative effect on crops by eliminating important pollinators, but the insects' population crash could also lead to other mosquitos coming with other diseases.
Mueller assures NPR's Rob Stein that the lab the mosquitos are in is very secure, adding that even if the mosquitos did escape they would not be able to survive Italy's climate. "To enter the most secure part of the facility, Mueller punches a security code into a keypad to open a sliding glass door," reports NPR. "As the door seals, a powerful blower makes sure none of the genetically modified mosquitoes inside escape. Anyone entering must don white lab coats to make it easier to spot any mosquitoes that might try to hitch a ride out of the lab and must pass through a second sealed door and blower."
The world is going to be transformed over the next few decades by work like this. Problems like malaria will be addressed. The bad news is that these early efforts carry unknown risks the good news is that the work is being done by experts in the field. This sort of work will be accessible to hackers in very few years so lets hope that regulated agencies beat them to it. If you thought the nuclear standoff of the cold war years was bad just wait for the biological equivalent. The genie is out of the bottle now, work like this is as much a part of national defense as hyper-sonic missiles.
Facts are history now plebs have politics for religion on social media.
Using that word in the title implies released into the wild, which is a headline grabber.
Let's get real.
They are tropical mosquitoes. They can't survive outdoors in Italy in February. They also can't interbreed with Italian mosquitoes.
Killing Anopheles (malaria) and Aedes aegypti (yellow fever, dengue, zika) will have little environmental repercussions because other non-vector mosquitoes can fill the same niche. Furthermore, these species are invasive species in many areas, displacing native mosquitoes. So exterminating them can help to restore the natural balance. Many islands, including Hawaii, have no native mosquito species.
Only about 200 of the 3,500 species of mosquitoes even bite man, and of those there are 5 species that spread disease. The ecosystem will do just fine.
They are tropical mosquitoes. They can't survive outdoors in Italy in February.
Those of us who are older might remember similar claims being made about Africanized Honeybees - yes they were wreaking havoc in South America, but they’d never make it past Panama because they couldn’t survive the climate. And they’d never, EVER make it to the US...
#DeleteChrome
We should not be going down that road AT ALL.
Are you willing to volunteer your child to help keep Plasmodium malariae from extinction?
Or are you only against extinction if the victims are black kids in Africa?
Corn doesn't contain any notable nutrients so how exactly is it supposed to end a famine?
Corn/maize is a good source of many minerals and micronutrients, and even contains reasonable amounts of protein, although it is deficient in lysine. Famine victims can't survive indefinitely on a 100% corn diet, but it has plenty of calories, and when combined with pulses (beans and peas) or supplemented with meat, fish, eggs, or dairy, it is nutritious.
There is more than one type of famine. Kwashiorkor is a type of starvation resulting from a lack of nutrients and protein deficiency, even if calories are adequate. Marasmus is starvation caused by lack of calories. Corn/maize can relieve either.