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According to Quantum mechanics truth is relative not absolute. According to philosophy of some religions too truth is relative. So I cannot say what I am saying about Genetically Modified crops is absolute truth. But I will try to be as close to truth as possible while dealing with this topic dogged by confusion, suspicion, polarised opinion and recrimination.

In a world where for every Monsanto, there will be hundreds of Vandana Shivas ( Indian activist who opposes GM crops), it is extremely difficult to come to a conclusion based on generalizations even for a scientifically literate person like me! I think case by case  study of the whole process of Genetically modified foods is important because one GM crop might differ from another, one experiment might differ from another and one cause (commercial) might differ from another (feeding the hungry) .

There are several theories, both for and against GM foods and crops. Both supporters and skeptics are trying their best to push forward what they believe in as truth. But broad statements about the value or risks from genetically modified organisms are pretty much useless, according to experts. The details matter more. It is necessary to understand the cultural, social and psychological roots of reactions to GM.

The truth is we need Biotechnology to feed the nearly 11 billion  people that are going to walk on this planet Earth in the decades to come.  To meet that challenge, we need every tool at our disposal: biotech, non-biotech, organic, conventional, local, regional, national and global.  Yes, we need to improve storage and distribution systems. But still after putting  efficient systems in place, we still fall short of required targets. So we cannot completely dismiss GM food. Moreover, benefits such as reduced pesticide use and its ecological impact cannot be ignored. In developing countries like India, where malnutrition and vitamin deficiency cause severe illnesses, complete banning of these GM crops like yellow rice is highly controversial (5,6)- oh, yes, some people say eating carrots is better than eating costly yellow rice). Starvation causes several hundred deaths globally every year, in large part because of malnutrition. Nobody has ever died directly because of GMO's. This is a fact! And some of the anti-GM studies are incomplete and inconclusive (4). Foods derived from GM crops have been consumed by hundreds of millions of people across the world for more than 20 years, with no reported ill effects (or legal cases related to human health), despite many of the consumers coming from that most litigious of countries, the USA (7). More than two-thirds of foods sold in the United States involve some GM product, estimates suggest, without any bad consequences. Even cattle fed on GM crop residues didn't show any side effects during various studies (8). We now have a large set of data, both experimental and observational, showing that genetically modified feed is safe and nutritionally equivalent to non-GMO feed. In the past 20 years, around 1,200 scientific studies, the "vast majority" of which were published in journals that have no financial ties to the food or agriculture industries, make the case for mainstream use of GMO's in food.There does not appear to be any health risk to the animals, and it is even less likely that there could be any health effect on humans who eat those animals. Majority of the scientists agree with this logic. A recent poll from the Pew Foundation found that nearly 90% of scientists from the American Association for the Advancement of Science (AAAS) – one of the world’s largest science bodies – have concluded that, based on increasingly mounting evidence, GM food is perfectly safe (9). And they think that people who disregard two decades of scientific research for some feel-good factor, are falling prey for a psuedo-scientific myth!

If you are taking insulin, odds are it's from GMO bacteria. And it's saving lives.

Medicines for other deadly diseases like malaria too are being developed by using GM modified yeast (13).

Genetically modified male cabbage moths feasting on the cabbage ( which carry a gene designed to kill progeny they sire with wild female moths )  are being used in the US to keep the agriculture pests in control and to restrict the use of harmful pesticides ( 14). 

The same people who are against GM food are perfectly willing to inject themselves with genetically engineered insulin if they are diabetics or genetically moleculed antibodies if they have lymphoma. What an irony!

Watch this video to know how genetically modified microbes can be used to clean up oil spills and plastic wastes:



Research shows that, ecologically, certain GMOs can have less than desirable impacts. But many effects can be predicted and worked around. GM salmon, for example, run the risk of interbreeding with native salmon of the North America. That’s why they are being raised in tanks far from salmon streams. Strict regulation of each proposed GM product — examining the details of its impacts — can be an effective way to deal with the potential risks. Another detail to consider in assessing risks is how they compare with benefits, such as the potential to increase large numbers of people’s food supplies and improve their health.

Humans have been genetically modifying foods through selective breeding for more than 10,000 years. Were it not for these original genetically modified organisms—and today's more engineered GMOs designed for resistance to pathogens and herbicides and for better nutrient profiles—the planet could sustain only a tiny fraction of its current population. Golden rice, for example, was modified to enhance vitamin A levels, in part, to help Third World children with nutritional deficiencies that have caused millions to go blind.

Natural mutations are occurring all over the world since living beings came into existence. When once the green revolution started, human beings started to produce good quality products by manipulating gene pools. There is nothing new in this. But commercialization of Agriculture has created some problems in recent times.

When there is some sort of genetic modifications occurring naturally as well as through artificial manipulations since ages why do people still fear and hate GM food and crops?

In a recent New Yorker article, Maria Konnikova returned to an explanation for these gut reactions that has been around at least since the early efforts at genetic engineering in the 1970s: The idea that fear and distrust of GMOs is based on ancient intuitive (but sometimes illog...

Psychologists have long observed, according to this article, that there is a continuum in what we perceive as natural or unnatural. As the psychologist Robert Sternberg wrote in 1982, the natural is what we find more familiar, while what we consider unnatural tends to be more novel—perceptually and experientially unfamiliar—and complex, meaning that more cognitive effort is required to understand it. The natural is seen as inherently positive; the unnatural is not. And anything that involves human manipulation is considered highly unnatural—like, say, G.M.O.s, even though genetically modified food already lines the shelves at grocery stores. As Michael Specter put it, “The history of agriculture is the history of humans breeding seeds and animals to produce traits we want in our crops and livestock.”

Therefore Ms Konnikova  points out that familiarity breeds the opposite of contempt. She takes the Enlightenment view that time is on the side of what she calls “increased rationality.” I do agree that familiarity will be a powerful dampener of Unreasoning Fear of GMOs. And we must realize that that people in some parts of the world are already eating lots of GM foods (espcially in the US) with no ill effects or  very insignificant  ones - at least till now!

Stefaan Blancke and his colleagues in their paper (10) titled "Fatal attraction: the intuitive appeal of GMO opposition" argue that people tend to rely on intuitive reasoning, instead of critical one to make a judgment on GMOs. This intuitive reasoning includes folk biology, teleological and intentional intuitions and disgust. Anti-GMO activists have exploited intuitions successfully to promote their cause. Intuitive judgments steer people away from sustainable solutions. According to them negative representations of GMOs are widespread and compelling because they are intuitively appealing. By tapping into intuitions and emotions that mostly work under the radar of conscious awareness, but are constituent of any normally functioning human mind, such representations become easy to think. They capture peoples' attention, they are easily processed and remembered and thus stand a greater chance of being transmitted and becoming popular, even if they are untrue. Thus, many people oppose GMOs, in part, because it just makes sense that they would pose a threat.
The solution, say the researches, lies in education starting from a young age and specifically targeted at tackling common misconceptions might immunize the population against unsubstantiated anti-GMO messages. Other concerns can be addressed and discussed in the wider context of agricultural practices and the place of science and technology in society. However, for now, the best way to turn the tide and generate a more positive public response to GMOs is to play into people’s intuitions as well. For instance, emphasizing the benefits of current and future GM applications — improved soil structures because herbicide resistant crops require less or no tilling, higher income for farmers in developing countries, reduced vitamin A deficiency, virus and drought resistance, to name a few — might constitute the most effective approach to changing people’s minds. Given the benefits and promises of GM technology, such a change is much needed.

What is alarming is opponents of GM crops and foods are propagating pseudo-science. They say GMOs are a product of rapacious, corporatist food and farming movements.  The primatologist Jane Goodall, who, in her 2013 book, Seeds of Hope, cites dubious research to support her anti-GMO claims: a 2001 study from the CDC which “found twenty-eight subjects had experienced apparent allergic reactions after ingesting GM corn.” But Goodall fails to mention that the CDC report did not provide “any evidence that the reactions that the affected people experienced were associated with hypersensitivity” to genetically modified corn.  GMOs evoke unnatural “Frankenfoods”: supersized, shiny tomatoes on steroids and mutant strawberries contaminated with bovine DNA.

But the pseudoscience that has given rise to these consumer fears has been thoroughly debunked in significant scientific studies and peer reviews. Anti-GMO campaigners have distorted the science on genetically modified foods to gain public confidence and spread fear among general population. 

A French research team purportedly found that GMO corn fed to rats caused them to develop giant tumors and die prematurely.

Within 24 hours, the study’s credibility was shredded by scores of scientists. The consensus judgment was swift and damning: The study was riddled with errors—serious, blatantly obvious flaws that should have been caught by peer reviewers. Many critics pointed out that the researchers chose a strain of rodents extremely prone to tumors. Other key aspects of the study, such as its sample size and statistical analysis, have also been highly criticized. That’s no stretch of the imagination, considering the history of the lead author, Gilles-Eric Seralini, who, as NPR reports, “has been campaigning against GM crops since 1997,” and whose research methods have been “questioned before,” according to the New York Times. The circumstances surrounding Seralini’s GMO rat-tumor study range from bizarre (as a French magazine breathlessly reports, it was conducted in clandestine conditions) to dubious (funding was provided by an anti-biotechnology organization whose scientific board Seralini heads). Seralini and his co-authors manipulated some members of the media to prevent outside scrutiny of their study. One University of Florida scientist suggests the study was “designed to frighten” the public. The paper was ultimately retracted but unfortunately still quoted by anti-GMO people. This GMO panic is more sensational than sense.

In her 2011 study in Scientific American, the prominent plant geneticist Pamela Ronald noted a “broad scientific consensus that genetically engineered crops currently on the market are safe to eat. 

After 14 years of cultivation and a cumulative total of 2 billion acres planted, no adverse health or environmental effects have resulted from commercialization of genetically engineered crops.”

Still, the fear of “Frankenfoods” remains so widespread, so deeply—if wrongly—embedded in the popular “natural” foods movement that Chipotle stands to commercialize hysteria and make a profit on its GMO ban.

 Entine, founder of the Genetic Literacy Project and senior fellow at the University California-Davis’s World Food Center, references the most comprehensive review of GMOs and food—a 2014 study compiling nearly 30 years of health data on more than 100 billion food-producing animals, both before and after the introduction of genetically engineered feed in 1996—as scientific proof that genetically modified foods are safe for human consumption. Published in the Journal of Animal Science, the review resulted in two crucial findings: first, that no nutritional variances were detected in food-products derived from animals who ate genetically modified feed; second, that these animals were just as healthy as those who ate non-GMO feed.

Where is the evidence that everyone else’s products lack integrity, as anti-GM campaigners suggest? GMO-free campaign is “profoundly mistaken, based on fear and misrepresentation.”


Fears about the environmental impact of GM organisms is the most important explanation people give for refusing GM crops. The other was fears about GM organisms in the human food chain. And both reflect deeply held concerns about the ethics and effects of tampering with nature. This concern relates not only to the direct and immediate physical impacts of ‘tampering’, but also to a fear of unforeseen longer-term repercussions. People explicitly relate this to considering the entire ecosystem in which we live as one system — a system in which a change to one part can have unexpected impacts in others.GM generally relates to organisms used for food, particularly plants. And although genetic modification intends to create organisms that better serve various human purposes, GM in food was a major concern. As the old adage has it, we are what we eat — and in the context of worries about ‘tampering’ with nature, it seems that people worry about introducing repercussions into their own bodies.
However, Scientists are making kill switches for GMOs to address this problem! ( 11) A genetic kill switch could prevent industrial espionage and environmental contamination. Once an engineered organism completes its task, it is useful to degrade the associated DNA to reduce environmental release and protect intellectual property. An environmentally dependent method to excise particular genes and eliminate genetically modified organisms (GMOs) if they leave the lab, published on May 19 in Nature Communications (12), uses an inducible CRISPR/Cas9 genome-editing system to snip out vital pieces of the E. coli genome.
The most recent published attempts at creating such a GMO “kill switch” relied on making the survival of genetically-modified bacteria dependent on synthetic amino acids that were only available under laboratory conditions. In the latest study, scientists at MIT created a system that would instead make fatal changes to the bacterial genome when triggered by a change in environmental conditions.

Two new kill switches known as “Deadman” and “Passcode” for this purpose. The system uses both switches to control the organism. Passcode allows the organism to detect specific changes in the environment. This then activates Deadman, which causes the organism to start producing a potent toxin that kills its cells.

The authors have demonstrated that different environmental signals, such as the gain or loss of a particular sugar nutrient source, can act as the control mechanism. This gives scientists some design flexibility when creating new kill switch systems for GMOs. The current research is based on bacteria, but in practical terms this technology could allow us to programme any GMO to “self-destruct”. For example, it might be possible to design GM crops that were programmed to die if they escaped from the growing area.

One issue still to be addressed though is that when some organisms die, their DNA can persist in the environment. In bacteria this can be a problem because certain bacteria can take up DNA from the environment by a process called natural genetic transformation. If the DNA led to beneficial characteristics, it could be assimilated into the bacteria’s genome to create a natural GMO. The answer to this particular issue may lie in other recent work that described a kill switch based on CRISPR technology.

CRISPRs are short sequences of DNA found in bacteria that are the remnants of a previous viral infection used to help the immune system. If a bacterium encounters the same infection again, the CRISPR system can recognise the virus and recruit a DNA-degrading enzyme that cuts up and destroys the invading viral DNA.

Researchers from MIT have used the CRISPR concept to create a kill switch that effectively erases DNA from GM bacteria. In this case, the code inserted into the GMO included the short sequences recognised by the CRISPR system. When the input signal for the kill switch was activated, CRISPR targeted and destroyed the inserted DNA, essentially returning the organism to its former non-GM state. Combining this system with other kill switches could allow scientists to be confident that neither a GMO nor its DNA could persist outside of a contained environment.

These developments demonstrate that scientists designing GMOs have taken on board public feedback. The question remains whether kill switch technology will address the concerns about the “escape” of GMOs and “contamination of the wild”. It is certainly a step in the right direction.

Another important aspect is making changes using epigenetics —involving the expression of existing genes and not the introduction of new genetic material from another plant—crops bred using this technology could sidestep controversy associated with genetically modified organisms and food (15). When plants are modified epigenetically, they can modify many genes in as simple a manner as possible. That includes adjusting the circadian clock—detecting light and triggering growth and reproductive phases—and modifying hormone responses to give them maximum flexibility, making them more resilient. By adjusting the epigenetic architecture of a plant, researchers were able to access its resiliency network, and see how genes are expressed quickly and broadly to adjust a plant's growth to adapt to the environment. Researchers contend that plants can be "reprogrammed" epigenetically to express genes differently without altering genotype, which constitutes a non-traditional approach to breeding. Because they can now identify gene networks that appear to be targeted by this manipulation, researchers report that plants have mechanisms designed to address stress or alter growth, and these can be accessed. Large scale experiments are now going on in this direction.

Researchers have also developed a new way to get CRISPR/Cas9 into plant cells without inserting foreign DNA. This allows for precise genetic deletions or replacements, without inserting foreign DNA. Therefore, the end product is not a genetically modified organism, or GMO (16).

Yes, scientists are taking the fears of people outside seriously and are taking the right steps to control GM technology.

And there is an interesting aspect to it, according to one of my scientist friends. Zucchini, squash, potatoes, and green peppers, when cooked, produce a chemical called acrylamide, a known carcinogen. Ironically, anti-GMO people shot themselves in the foot recently, showing how uneducated they are and how woefully ignorant of basic biology they are. A GMO potato called the Innate potato has been developed that does not produce acrylamide. That is, the Innate GMO potato has less cancer risk than normal potatoes; it was specifically engineered to remove a known carcinogen. But the howls of fury from the anti-GMO activists prevented its adoption. Very bad!


People from developing countries see powerful countries, and companies which export GM organisms, as introducing danger — if not knowingly then uncaringly.
Because... they say...

The first step in genetically engineering plants, the process of cutting and splicing genes in the test tube, is precise, but subsequent steps are not. In particular, the process of inserting a genetically modified gene into the DNA of a plant cell is crude, uncontrolled, and imprecise, and causes mutations – heritable changes – in the plant’s DNA blueprint. These mutations can alter the functioning of the natural genes of the plant in unpredictable and potentially harmful ways. Other procedures associated with producing GM crops, including tissue culture, also produce mutations.

In addition to the unintended effects of mutations, there is another way in which the GM process generates unintended effects. Promoters of GM crops paint a picture of GM technology that is based on a naïve and outdated understanding of how genes work. They propagate the simplistic idea that they can insert a single gene with laser-like precision and insertion of that gene will have a single, predictable effect on the organism and its environment. But manipulating one or two genes does not just produce one or two desired traits. Instead, just a single change at the level of the DNA can give rise to multiple changes within the organism. These changes are known as pleiotropic effects. They occur because genes do not act as isolated units but interact with one another, and the functions and structures that the engineered genes confer on the organism interact with other functional units of the organism. Because of these diverse interactions, and because even the simplest organism is extremely complex, it is impossible to predict the impacts of even a single GM gene on the organism. It is even more impossible to predict the impact of the GMO on its environment – the complexity of living systems is too great.

According to scientists, when we are selecting the traits for genetic modifications, we are selecting only the beneficial ones. Even if the wild plants get these genes, they are desired qualities like disease resistance or enhanced vitamin production. We need not worry about them. In order to maintain the position that GMOs are not adequately tested, or that they are harmful or risky, you have to either highly selectively cherry pick a few outliers of low scientific quality, or you have to simply deny the science.

Read how scientists are addressing the concerns of public about GMOs and how they are disproving the false propaganda about them : Will GMOs Hurt My Body? The Public’s Concerns and How Scientists Have Addressed Them http://sitn.hms.harvard.edu/flash/How scientists have addressed teh...

Watch this video that wonderfully discusses all the controversies related to GM foods:

The Indian Government recently told the Supreme court of the country that GM crops are must for a country like India(1) because it could not achieve the goal of reducing the number of hungry people by half without taking recourse to genetically modified crops, which could herald the second green revolution in the country. The central government said GM crops would not only lead to increased food security but would also reduce pressure on land use. In the last 13 years, the average availability of land per head had shrunk from 0.21 hectares to 0.10 hectares. While the population had increased by 181 million in the last decade, the land under sowing remained static at 140-143 million hectares since 1970. Pitching for field trials of GM crops, the government said: "Genetic engineering promises remarkable advances in medicine, agriculture and other fields." "Ban on GM crop field trials will be highly detrimental and not in national interest," the central government said in its affidavit. In an attempt to persuade the apex court to reject the recommendation of the TEC, the central government's affidavit said: "In biotechnology and genetics, the principle sciences behind the GM crops, India has done exceedingly well in investing in HRD, education and training since 1986 with the establishment of department of biotechnology, the first country to do so globally."It added that the success of the green revolution was driven by sufficient human resources available. Making a strong plea for field trials of GM crops, the government said that "a 10-year moratorium would have a "cascading effect" of putting all the related research fields which thus far on the upswing into a decline". It added that it would be a "blow to Indian science as it would put the country 20 years back in scientific research in comparison to fast growing economies who are developing GM crops like Brazil, China etc".
But some of the experts here asked the Prime Minister of India to ban GM field trials (2). According to 256 experts in Molecular Biology, Bio-diversity, Nutrition Science, Toxicology and various other fields of science, 'There is undue haste in getting GMOs released into the environment while the science behind its development is still controversial and evolving. However, some of them say they have no objections to conducting field trials in a covered green house, the practice of conducting open field trials without the use of nets would adversely affect cross-pollination and thereby India's Biodiversity. They also pointed out most of the studies that claimed GM products as being safe were conducted by biotechnology companies that were responsible for commercializing these GM crops and that they were concerned at the major gaps in the regulatory system that needed to be addressed before it became advisable to conduct more field trials. Some of them even say "GM crops are one of the biggest scientific frauds that the biotech seed industry is pulling off on India!
Well, we heard both sides of the story and the opposite arguments. Now it is time to do thorough thinking on these aspects.
There are four things to consider before us:
(1) We cannot completely avoid GM crops and foods because we have to feed the ever increasing population of the world. Therefore shutting the doors on GM crops is not possible. Insulin production using genetically modified bacteria and other medical benefits to save lives are not things that can be ignored.
(2) Yes, Genetic Modification is not a full proof option right now for people who fear them. Most of the studies are although satisfactorily conducted they cannot conclude anything with certainty at the moment. But I think 20 years of observation that says GM products are safe is a point to ponder. Moreover, we cannot put all GM crops in one basket and say they are bad. Each case must be investigated individually and should be dealt with according to the conclusion of the studies by the experts.
(3) People express concern about humanity’s potential, through science, to be ‘out of control’. This needs to be both understood and taken into consideration in making decisions about GM. Opposition won’t just fade just because the scientific community wishes it — we need to understand and respond to it better.
(4) There are scientists who are trying some safe methods. Creating Tastier and Healthier Fruits and Veggies with a Modern Alternative to GMOs by combining traditional plant breeding with ever-faster genetic sequencing tools, researchers are making fruits and vegetables more flavorful, colorful, shapely and nutritious (ref 3). Therefore, searching for more safer foods produced by other methods is the best option till GM foods are proved to be completely safe by time (how much time do we need still?) and expertise to people who oppose them.

And after reading this article of mine some people  asked me whether  I would eat GM foods if told that before hand. My instant answer : " Yes, I would, without any hesitation". Majority of the scientists would!


References:
1. http://www.deccanchronicle.com/121112/news-current-affairs/article/...
2. Deccan Chronicle 22 nd Nov., 2013 Issue (article titled 'Ban GM field Trials:Experts')

3. http://www.scientificamerican.com/article/creating-tastier-and-heal...

4. http://www.asianscientist.com/in-the-lab/philippine-gm-eggplant-2014/

5. http://journals.cambridge.org/action/displayFulltext?type=6&fid...
6. http://blogs.scientificamerican.com/guest-blog/2014/03/15/golden-ri...

7. http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2408621/
8. http://www.forbes.com/sites/jonentine/2014/09/17/the-debate-about-g...
9. http://tle-online.com/news/scotland-bans-gm-crops-and-all-of-scienc...
10. http://www.cell.com/trends/plant-science/abstract/S1360-1385%2815%2...
11. http://www.scientificamerican.com/article/why-scientists-are-making...
12. http://www.nature.com/ncomms/2015/150519/ncomms7989/full/ncomms7989...

13. http://www.nature.com/articles/nature04640.epdf?referrer_access_tok...

14, https://www.scientificamerican.com/article/sex-battle-in-the-sky-ge...

15. https://phys.org/news/2020-05-memory-stress-progeny-resilient.html?...

16. https://phys.org/news/2020-05-crispr-non-gmo-method.html?utm_source...

Views: 2371

Replies to This Discussion

"Rewilding"
If the name is genetically modified organism, or G.M.O., which many people are dead set against. But what if scientists used the precise techniques of today’s molecular biology to give back to plants genes that had long ago been bred out of them? And what if that process were called “rewilding?”
"Feasibility of new breeding techniques for organic farming"
.Organic farming suffers from lower productivity than conventional agriculture because the use of pesticides, herbicides, and fertilizers is restricted.
•Rewilding furnishes crops with lost properties that their ancestors once had to tolerate adverse environmental conditions.
•Rewilding is in accordance with the values of organic breeding and would contribute to closing the yield gap.
•New breeding techniques that involve methods of genetic engineering allow for rewilding in a way that the final crop cannot be distinguished from a crop bred by traditional means.

Organic farming is based on the concept of working ‘with nature’ instead of against it; however, compared with conventional farming, organic farming reportedly has lower productivity. Ideally, the goal should be to narrow this yield gap. In this review, we specifically discuss the feasibility of new breeding techniques (NBTs) for rewilding, a process involving the reintroduction of properties from the wild relatives of crops, as a method to close the productivity gap. The most efficient methods of rewilding are based on modern biotechnology techniques, which have yet to be embraced by the organic farming movement. Thus, the question arises of whether the adoption of such methods is feasible, not only from a technological perspective, but also from conceptual, socioeconomic, ethical, and regulatory perspectives.
http://www.cell.com/trends/plant-science/abstract/S1360-1385%2815%2...

Is opposition to genetically modified food irrational?
http://www.bbc.com/news/science-environment-32901834

1273

Bt products are found to be safe for use in the environment and with mammals. The EPA (environmental protection agency) has not found any human health hazards related to using Bt. In fact the EPA has found Bt safe enough that it has exempted Bt from food residue tolerances, groundwater restrictions, endangered species labeling and special review requirements. Bt is often used near lakes, rivers and dwellings, and has no known effect on wildlife such as mammals, birds, and fish.

Humans exposed orally to 1000 mg/day for 3-5 days of Bt have showed no ill effects. Many tests have been conducted on test animals using different types of exposures. The results of the tests showed that the use of Bt causes few if any negative effects. Bt does not persist in the digestive systems of mammals.

Bt is found to be an eye irritant on test rabbits. There is very slight irritation from inhalation in test animals which may be caused by the physical rather than the biological properties of the Bt formulation tested.

Bt has not been shown to have any chronic toxicity or any carcinogenic effects. There are also no indication that Bt causes reproductive effects or birth defects in mammals.

Bt breaks down readily in the environment. Because of this Bt poses no threat to groundwater. Bt also breaks down under the ultraviolet (UV) light of the sun.

Even with such widespread use of Bt-based products in the past 50 years, only two incidents of repored allergic reaction have been reported to the EPA. In the first incident, it was concluded that the exposed individual was suffering from a previously diagnosed disease. The second involved a person that had a history of life-threatening food allergies.Upon investigation, it was found that the formulation of Bt also contained carbohydrate and preservatives which have been implicated in food allergy.

http://www.bt.ucsd.edu/bt_safety.html

Reference: Bacillus thuringiensis: Biology, Ecology and Safety, Glare, T.R., O'Callaghan, M. (2000) ISBN 0-471-49630-8

Why Scientists Are Making Kill Switches for GMOs

A genetic kill switch could prevent industrial espionage and environmental contamination
Untold numbers of genetically modified Escherichia coli bacteria live in vats around the world, churning out useful things such as medical insulin, plastic polymers and food additives. When the reprogrammed bugs have served their role, they are packed away as industrial waste or repurposed for fertilizer.

This arrangement currently poses little environmental risk because genetically modified E. coli is weak compared with its wild cousins; it would not survive for long outside the lab. But engineered bugs not yet invented might go where they are not wanted and create risks. What if, say, an accident released more resilient engineered bugs that took over a well-balanced ecosystem? Or if tweaked bacteria shared modifications such as antibiotic resistance with their counterparts in nature through horizontal gene transfer? Or if a rival firm stole a patented bacterium for the trade secrets encoded in its DNA? Scientists are developing fail-safes for such contingencies.
http://www.scientificamerican.com/article/why-scientists-are-making...

More than 100 Nobel laureates have signed a letter urging Greenpeace to end its opposition to genetically modified organisms (GMOs). The letter asks Greenpeace to cease its efforts to block introduction of a genetically engineered strain of rice that supporters say could reduce Vitamin-A deficiencies causing blindness and death in children in the developing world.

"We urge Greenpeace and its supporters to re-examine the experience of farmers and consumers worldwide with crops and foods improved through biotechnology, recognize the findings of authoritative scientific bodies and regulatory agencies, and abandon their campaign against 'GMOs' in general and Golden Rice in particular," the letter states.
The letter campaign was organized by Richard Roberts, chief scientific officer of New England Biolabs and, with Phillip Sharp, the winner of the 1993 Nobel Prize in physiology or medicine for the discovery of genetic sequences known as introns. The campaign has a website, supportprecisionagriculture.org, that includes a running list of the signatories.
“We’re scientists. We understand the logic of science. It's easy to see what Greenpeace is doing is damaging and is anti-science," Roberts told The Washington Post. “Greenpeace initially, and then some of their allies, deliberately went out of their way to scare people. It was a way for them to raise money for their cause."

Roberts said he endorses many other activities of Greenpeace, and said he hopes the group, after reading the letter, would "admit that this is an issue that they got wrong and focus on the stuff that they do well."
The letter states:

Scientific and regulatory agencies around the world have repeatedly and consistently found crops and foods improved through biotechnology to be as safe as, if not safer than those derived from any other method of production. There has never been a single confirmed case of a negative health outcome for humans or animals from their consumption. Their environmental impacts have been shown repeatedly to be less damaging to the environment, and a boon to global biodiversity.
Greenpeace has spearheaded opposition to Golden Rice, which has the potential to reduce or eliminate much of the death and disease caused by a vitamin A deficiency (VAD), which has the greatest impact on the poorest people in Africa and Southeast Asia.

The World Health Organization estimates that 250 million people, suffer from VAD, including 40 percent of the children under five in the developing world. Based on UNICEF statistics, a total of one to two million preventable deaths occur annually as a result of VAD, because it compromises the immune system, putting babies and children at great risk. VAD itself is the leading cause of childhood blindness globally affecting 250,000 - 500,000 children each year. Half die within 12 months of losing their eyesight.

The scientific consensus is that that gene editing in a laboratory is not more hazardous than modifications through traditional breeding, and that engineered plants potentially have environmental or health benefits, such as cutting down on the need for pesticides. A report by the National Academies of Sciences, Engineering and Medicine, released in May, said there is no substantiated evidence that GMO crops have sickened people or harmed the environment, but also cautioned that such crops are relatively new and that it is premature to make broad generalizations, positive or negative, about their safety.

[Are GMO crops safe? Scientists weigh in, saying the focus should be on the plant and not the process.]

https://www.washingtonpost.com/news/speaking-of-science/wp/2016/05/...

I think we must also listen to other experts who are trying to show different angles to this controversy:

 

AI combined with CRISPR precisely controls gene expression

Artificial intelligence can predict on- and off-target activity of CRISPR tools that target RNA instead of DNA, according to new research published in Nature Biotechnology.

he study by researchers at New York University, Columbia University, and the New York Genome Center, combines a  with CRISPR screens to control the expression of human  in different ways—such as flicking a light switch to shut them off completely or by using a dimmer knob to partially turn down their activity. These precise gene controls could be used to develop new CRISPR-based therapies.

CRISPR is a gene editing technology with many uses in biomedicine and beyond, from treating sickle cell anemia to engineering tastier mustard greens. It often works by targeting DNA using an enzyme called Cas9. In recent years, scientists discovered another type of CRISPR that instead targets RNA using an enzyme called Cas13.

RNA-targeting CRISPRs can be used in a wide range of applications, including RNA editing, knocking down RNA to block expression of a particular gene, and high-throughput screening to determine promising drug candidates. Researchers at NYU and the New York Genome Center created a platform for RNA-targeting CRISPR screens using Cas13 to better understand RNA regulation and to identify the function of non-coding RNAs. Because RNA is the main genetic material in viruses including SARS-CoV-2 and flu, RNA-targeting CRISPRs also hold promise for developing new methods .... Also, in human cells, when a gene is expressed, one of the first steps is the creation of RNA from the DNA in the genome.

A key goal of the study is to maximize the activity of RNA-targeting CRISPRs on the intended target RNA and minimize activity on other RNAs which could have detrimental side effects for the cell. Off-target activity includes both mismatches between the guide and target RNA as well as insertion and deletion mutations.

Earlier studies of RNA-targeting CRISPRs focused only on on-target activity and mismatches; predicting off-target activity, particularly insertion and deletion mutations, has not been well-studied. In human populations, about one in five mutations are insertions or deletions, so these are important types of potential off-targets to consider for CRISPR design.

"Similar to DNA-targeting CRISPRs such as Cas9, we anticipate that RNA-targeting CRISPRs such as Cas13 will have an outsized impact in  and biomedical applications in the coming years," said Neville Sanjana, associate professor of biology at NYU, associate professor of neuroscience and physiology at NYU Grossman School of Medicine, a core faculty member at New York Genome Center, and the study's co-senior author. "Accurate guide prediction and off-target identification will be of immense value for this newly developing field and therapeutics."

In their study in Nature Biotechnology, Sanjana and his colleagues performed a series of pooled RNA-targeting CRISPR screens in human cells. They measured the activity of 200,000 guide RNAs targeting essential genes in human cells, including both "perfect match" guide RNAs and off-target mismatches, insertions, and deletions.

Sanjana's lab teamed up with the lab of  expert David Knowles to engineer a deep learning model they named TIGER (Targeted Inhibition of Gene Expression via guide RNA design) that was trained on the data from the CRISPR screens. Comparing the predictions generated by the deep learning model and  in , TIGER was able to predict both on-target and off-target activity, outperforming previous models developed for Cas13 on-target guide design and providing the first tool for predicting off-target activity of RNA-targeting CRISPRs.

"Machine learning and deep learning are showing their strength in genomics because they can take advantage of the huge datasets that can now be generated by modern high-throughput experiments. Importantly, we were also able to use 'interpretable machine learning' to understand why the model predicts that a specific guide will work well," said Knowles, assistant professor of computer science and systems biology at Columbia University's School of Engineering and Applied Science, a core faculty member at New York Genome Center, and the study's co-senior author.

"Our earlier research demonstrated how to design Cas13 guides that can knock down a particular RNA. With TIGER, we can now design Cas13 guides that strike a balance between on-target knockdown and avoiding off-target activity," said Hans-Hermann (Harm) Wessels, the study's co-first author and a senior scientist at the New York Genome Center, who was previously a postdoctoral fellow in Sanjana's laboratory.

The researchers also demonstrated that TIGER's off-target predictions can be used to precisely modulate gene dosage—the amount of a particular gene that is expressed—by enabling partial inhibition of gene expression in cells with mismatch guides. This may be useful for diseases in which there are too many copies of a gene, such as Down syndrome, certain forms of schizophrenia, Charcot-Marie-Tooth disease (a hereditary nerve disorder), or in cancers where aberrant gene expression can lead to uncontrolled tumor growth.

"Our deep learning model can tell us not only how to design a guide RNA that knocks down a transcript completely, but can also 'tune' it—for instance, having it produce only 70% of the transcript of a specific gene," said Andrew Stirn, a Ph.D. student at Columbia Engineering and the New York Genome Center, and the study's co-first author.

By combining  with an RNA-targeting CRISPR screen, the researchers envision that TIGER's predictions will help avoid undesired off-target CRISPR activity and further spur development of a new generation of RNA-targeting therapies.

"As we collect larger datasets from CRISPR screens, the opportunities to apply sophisticated machine learning models are growingly rapid. We are lucky to have David's lab next door to ours to facilitate this wonderful, cross-disciplinary collaboration. And, with TIGER, we can predict off-targets and precisely modulate gene dosage which enables many exciting new applications for RNA-targeting CRISPRs for biomedicine," said Sanjana.

This latest study further advances the broad applicability of RNA-targeting CRISPRs for human genetics and drug discovery, building on the NYU team's prior work to develop guide RNA design rules, target RNAs in diverse organisms including viruses like SARS-CoV-2, engineer protein and RNA therapeutics, and leverage single-cell biology to reveal synergistic drug combinations for leukemia.

More information: Prediction of on-target and off-target activity of CRISPR–Cas13d guide RNAs using deep learning, Nature Biotechnology (2023). DOI: 10.1038/s41587-023-01830-8

https://phys.org/news/2023-06-ai-combined-crispr-precisely-gene.htm...

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