Genetic innovation:
‘Nothing that we eat is natural’
‘Nothing that we eat is natural’
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 The elephant in the room. The human population grew slowly for thousands of years, but in recent centuries, it has jumped dramatically. Between 1900 and 2000, the increase in world population was three times greater than during the entire previous history of humanity giving an increment from 1.5 to 6.1 billion in just 100 years. How to feeding 10 billion people sustainably in the late 21st century? In just 30 to 40 years, about 600 quadrillion calories every single day is going to be required. This is twice as much as today. The mass of 7‐8 billion people will be squeezed in cities spending around 2800km3 of fresh water a year. That is more than the whole of irrigation farming is using, today. Every second 750 tons of topsoil is lost even today, giving a warning that present food production is unsustainable in the long term. Moreover, we have lost 24% of our land, already, and we keep on losing 1% a year. The UK’s Hadley Climate Centre projects that 40 per cent of the planet could be in regular drought by 2100. The hunger breeds war. If we failed to prevail what is coming, the consequences would affect every person on the planet.The road to hell is paved with good intentions. “The Earth provides enough to satisfy every man’s need, but not enough for every man’s greed” (cit. Mahatma Gandhi). The full intensification of agricultural production began in the middle of the previous century. The second half of the twentieth century was marked by the "green revolution", which significantly increased the yield of basic agricultural crops by a significant change in plant architecture. It was a project of great American foundations (Rockefeller, Ford) and governments of developing countries. The intensive agricultural production was based on new genotypes that were more distanced from their wild relatives, and highly dependent on human nursing. Though, the “Green agricultural revolution” has never solved "hunger problem in the world" as the proclaimed goal, the road of agricultural production was traced. Trying harder or the border is reached. The genetic variability meant to carry out the yield regardless of costs seems to be exhausted. The trying in breeding for special purposes, like to prevail stress conditions and seize new areas for food production, or revive branched wheat could appear insufficient. Are we to find new genetic variability capable to speed up food production, which is inadequately slow, now, making more turns? Are we to go NASA way, and try to avoid climate changes and field stresses in closed production systems? Does the vertical gene transfer reach the border of its potentials? Is the horizontal gene transfer, we still know so little about, the path of salvation? While vertical gene transfer has its limits relying on reproductive mechanisms and chromosomal compatibility in creating novel genetic recombination, horizontal gene transfer bypasses all these obstacles recombining at nucleic acid level, directly. Anyway, in order to prevail, it seems that new “revolution” is required, not only in doing, but also in thinking. The elephant is in the room, and we cannot ignore it, trying to solve the problem rearranging old furniture. Dramatic challenges require resolute response. . |
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https://www.flickr.com/photos/nataliemaynor/2539111053
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The world is in constant need of more food and new genetic engineering methods such as the CRISPR gene editing method offer a solution. However, these remain contested, EURACTIV Germany reports.
The banana looks very different to how it used to. Its original shape is actually small, thick, somewhat round and full of seeds. Its modern supermarket relative is, however, as most fruit and vegetables, the result of a human-led and goal-oriented plant breeding effort.
Already since the 1930s, genetic engineering has allowed for more efficient plant breeding possibilities. Yet genetic modification, even if not damaging to one’s health, is being debated from an ideological standpoint.
“It is a discussion with regards to the system. The big question is being addressed: what type of agricultural policies do we want for our future?” said Jon Falk, CEO of German plant breeding company Saaten-Union Biotec, during a conference on new methods of plant breeding organised by EURACTIV on Friday (22 March).
A categorical no to new techniques would be a waste of many new possibilities, as he said: “This is not black and white, we need a lot of grey in between.”
Falk’s laboratory represents middle-sized breeding companies in his sector, it is hoped that new genetic manipulation techniques will lead to higher yields of fruit and vegetable harvests.
This should help cover the rising global need for food. Yet, critics have doubts as genetically modified organisms (GMOs) could negatively impact the environment.
A recent judgement from the European Court of Justice in the case of “CRISPR/Cas9 gene editing” kick-started a debate in July 2018.
The technique is considered relatively simple and cost-efficient and allows for plants to be resistant to weather conditions, bacteria, certain fungus types and herbicides, and can be slightly healthier for people.
According to the Court of Justice’s judgment, the gene editing method must be labelled as genetic manipulation. Plants that are grown in this manner, therefore, cannot be sold throughout the EU without permission and the appropriate label.
For experts, the judgment was surprising. That is because genetic mutation through the CRISPR technique is no different than point mutations that occur naturally on a permanent basis.
“I consider the argument that the CRISPR method has the same effect as natural mutations to be muddying the debate. Two things are being mixed up deliberately”, said Harald Ebner, speaker for the German Green Party on genetic engineering and the bio-economy.
It is crucial that mankind needs to deliberate on appropriate technical possibilities as well as potential regulation and reparation mechanisms. A clear political line needs to be drawn.
Traditional plant breeding with chemistry and irradiation
Interestingly, genetically modified foods are not banned per se in the EU, but they still need to be vetted by the European Food Safety Agency (EFSA) and given the green light by member states.
A list of foodstuffs generally permitted throughout the EU can be found on the EU Commission’s online journal. Numerous types of corn, rapeseed, cotton, soy and sugar beet are listed there.
Taken from strong EU laws on genetic engineering are plants that have mutated via mutagenesis.
With this method that has been applied for decades, seeds will mutate due to a chemical bath or nuclear irradiation and grow into the most appropriate and pure mutated seed.
These are the basis for a great number of today’s food. Without the mutagenesis, there would not be wheat to produce pasta, and even the yeast that produces our beer has grown in that manner.
“Nothing that we eat is natural. Nothing grows in a free and natural environment as these plants would not even survive there,” explained geneticist Sascha Laubinger from Oldenburg University during the conference.
Laubinger is convinced that from a scientific standpoint, the classification of the CRISPR method as genetic engineering is incomprehensible.
That is because it cannot be differentiated from naturally mutated plants and because traditional mutagenesis causes a greater number of mutations compared to mutations that occur due to the gene editing technique.
“And we eat those every day,” he added.
But the genetic editing technique cannot be applied just once, theoretically, the genome can be cut at 10 or 100 locations. Where the line should be drawn should be a matter of politics, according to Laubinger.
For him, a line should be drawn where species are being crossbred. For example, humans and potatoes need to be kept separate.
Who benefits from new genetic engineering methods?
To put a stop to this, Ebner, speaker for the Green Party, is pleading for a stronger limitation on CRISPR genetic editing.
“When genetic engineering is completely deregulated, it is possible that committed mistakes cannot be corrected at a later stage,” he warned.
Representatives of the seed industry such as Jon Falk are more open about this: “These new techniques are not a panacea, but they can be an important tool for a sustainable change of the agricultural industry.
“That is why we need an open and ideology-free discussion with regards to genetic manipulation,” he added.
Falk is also concerned that limiting CRISPR technology too much could slow down Europe’s research compared to international competition. “This technique has application possibilities that could go beyond genetic engineering,” he argued.
For other developments, there would be a lack of experience. Big companies such as Bayer that practice genetic research and hope for increased sales of their pesticides would benefit a great deal according to critics.
The president of the German Agricultural Society (DLG), Hubertus Paetow, sees this differently: “The mutagenesis is a relatively simple process that small companies can also apply. These technologies could even boost the majority of the corporate landscape.”
Whether genetically modified plants are actually easier to take care of and more environmentally friendly, as its proponents contend, cannot be explicitly confirmed.
A 2016 study commissioned by the US American National Academy of Sciences found that farmers are less prone to using insecticides when they grow genetically modified plants.
On the other hand, they are using more plant protection products, which mean weeds become immune to herbicides.
All experts agree on one issue: the debate regarding genetic manipulation needs to change because its bad reputation is not in line with the times considering the opportunities that it presents.
Historically, a great number of foodstuffs have been grown and modified. The greater the possibilities of genetic engineering become, the more a consensus on the matter is needed with regard to what belongs on one’s plate – and what does not. [Edited by Gerardo Fortuna, Sam Morgan]
Already since the 1930s, genetic engineering has allowed for more efficient plant breeding possibilities. Yet genetic modification, even if not damaging to one’s health, is being debated from an ideological standpoint.
“It is a discussion with regards to the system. The big question is being addressed: what type of agricultural policies do we want for our future?” said Jon Falk, CEO of German plant breeding company Saaten-Union Biotec, during a conference on new methods of plant breeding organised by EURACTIV on Friday (22 March).
A categorical no to new techniques would be a waste of many new possibilities, as he said: “This is not black and white, we need a lot of grey in between.”
Falk’s laboratory represents middle-sized breeding companies in his sector, it is hoped that new genetic manipulation techniques will lead to higher yields of fruit and vegetable harvests.
This should help cover the rising global need for food. Yet, critics have doubts as genetically modified organisms (GMOs) could negatively impact the environment.
A recent judgement from the European Court of Justice in the case of “CRISPR/Cas9 gene editing” kick-started a debate in July 2018.
The technique is considered relatively simple and cost-efficient and allows for plants to be resistant to weather conditions, bacteria, certain fungus types and herbicides, and can be slightly healthier for people.
According to the Court of Justice’s judgment, the gene editing method must be labelled as genetic manipulation. Plants that are grown in this manner, therefore, cannot be sold throughout the EU without permission and the appropriate label.
For experts, the judgment was surprising. That is because genetic mutation through the CRISPR technique is no different than point mutations that occur naturally on a permanent basis.
“I consider the argument that the CRISPR method has the same effect as natural mutations to be muddying the debate. Two things are being mixed up deliberately”, said Harald Ebner, speaker for the German Green Party on genetic engineering and the bio-economy.
It is crucial that mankind needs to deliberate on appropriate technical possibilities as well as potential regulation and reparation mechanisms. A clear political line needs to be drawn.
Traditional plant breeding with chemistry and irradiation
Interestingly, genetically modified foods are not banned per se in the EU, but they still need to be vetted by the European Food Safety Agency (EFSA) and given the green light by member states.
A list of foodstuffs generally permitted throughout the EU can be found on the EU Commission’s online journal. Numerous types of corn, rapeseed, cotton, soy and sugar beet are listed there.
Taken from strong EU laws on genetic engineering are plants that have mutated via mutagenesis.
With this method that has been applied for decades, seeds will mutate due to a chemical bath or nuclear irradiation and grow into the most appropriate and pure mutated seed.
These are the basis for a great number of today’s food. Without the mutagenesis, there would not be wheat to produce pasta, and even the yeast that produces our beer has grown in that manner.
“Nothing that we eat is natural. Nothing grows in a free and natural environment as these plants would not even survive there,” explained geneticist Sascha Laubinger from Oldenburg University during the conference.
Laubinger is convinced that from a scientific standpoint, the classification of the CRISPR method as genetic engineering is incomprehensible.
That is because it cannot be differentiated from naturally mutated plants and because traditional mutagenesis causes a greater number of mutations compared to mutations that occur due to the gene editing technique.
“And we eat those every day,” he added.
But the genetic editing technique cannot be applied just once, theoretically, the genome can be cut at 10 or 100 locations. Where the line should be drawn should be a matter of politics, according to Laubinger.
For him, a line should be drawn where species are being crossbred. For example, humans and potatoes need to be kept separate.
Who benefits from new genetic engineering methods?
To put a stop to this, Ebner, speaker for the Green Party, is pleading for a stronger limitation on CRISPR genetic editing.
“When genetic engineering is completely deregulated, it is possible that committed mistakes cannot be corrected at a later stage,” he warned.
Representatives of the seed industry such as Jon Falk are more open about this: “These new techniques are not a panacea, but they can be an important tool for a sustainable change of the agricultural industry.
“That is why we need an open and ideology-free discussion with regards to genetic manipulation,” he added.
Falk is also concerned that limiting CRISPR technology too much could slow down Europe’s research compared to international competition. “This technique has application possibilities that could go beyond genetic engineering,” he argued.
For other developments, there would be a lack of experience. Big companies such as Bayer that practice genetic research and hope for increased sales of their pesticides would benefit a great deal according to critics.
The president of the German Agricultural Society (DLG), Hubertus Paetow, sees this differently: “The mutagenesis is a relatively simple process that small companies can also apply. These technologies could even boost the majority of the corporate landscape.”
Whether genetically modified plants are actually easier to take care of and more environmentally friendly, as its proponents contend, cannot be explicitly confirmed.
A 2016 study commissioned by the US American National Academy of Sciences found that farmers are less prone to using insecticides when they grow genetically modified plants.
On the other hand, they are using more plant protection products, which mean weeds become immune to herbicides.
All experts agree on one issue: the debate regarding genetic manipulation needs to change because its bad reputation is not in line with the times considering the opportunities that it presents.
Historically, a great number of foodstuffs have been grown and modified. The greater the possibilities of genetic engineering become, the more a consensus on the matter is needed with regard to what belongs on one’s plate – and what does not. [Edited by Gerardo Fortuna, Sam Morgan]
