European Court of Justice delivers no justice to Europe on genome‐edited crops


Letter

European Court of Justice delivers no justice to Europe on
genome-edited crops
Alan H. Schulman1,2,3,†* , Kirsi-Marja Oksman-Caldentey4 and Teemu H. Teeri3,5

1Production Systems, Natural Resources Institute Finland (Luke), Helsinki, Finland
2Institute of Biotechnology, University of Helsinki, Helsinki, Finland
3Viikki Plant Science Centre, Helsinki, Finland
4VTT Technical Research Centre of Finland Ltd., Espoo, Finland
5Department of Agricultural Sciences, University of Helsinki, Helsinki, Finland

Received 11 April 2019;

revised 3 June 2019;

accepted 5 June 2019.

*Correspondence (Tel +358 40 768 2242;

email alan.schulman@helsinki.fi)
†A.H.S. is President of the European Plant

Science Organisation, EPSO

Keywords: genome editing, GMO

regulations, NBT, new breeding

techniques, CRISPR/Cas.

Genetic variation is natural and needed for crop
improvement

The advent of agriculture about ten millennia ago, the Green

Revolution of the 1960s, and all agriculture in-between and since

were founded on identification and use of genetic variation.

Traditional farmers selected higher producing or better tasting

variants and propagated them. The 19th-century advent of plant

breeding exploited variation by use of sexual crosses. The science

of breeding made great progress through the application of

Mendelian, quantitative, and population genetics, heterosis, and

ultimately molecular markers and genomic selection. However,

modern breeders in essence still search for the variation that gives

needed traits and introduce it into their breeding programmes.

The rest is just combining alleles.

However, there is only finite variation within our crop

species, and genetic incompatibility limits the amount that can

be introgressed from outside the species. Moreover, wide

crosses with exotic germplasm can bring, together with the

desired trait such as disease resistance, many undesired traits

such as seed shattering or low yield, which had been earlier

painstakingly bred out of the elite parent. After LJ Stadler

demonstrated the use of X-rays to mutagenize barley and

maize (Stadler, 1930), breeders began to create their own

variation, using random mutagenesis followed by selection,

called ‘mutation breeding’. At the beginning of 2019, the joint

FAO/IAEA mutant variety database (mvd.iaea.org/) contained

3284 plant varieties released in more than 60 countries, which

were either the direct products of mutagenesis or their

progeny. These span at least 214 plant species, including not

only the major cereals and grain legumes, but also oil crops,

fibre crops, herbs, fruits and ornamentals. Prominent examples

include the following: the rice varieties Amaroo (Australia),

Zhefu 802 (China), RD6 and RD15 (Thailand); the malting

barley varieties Diamant and Golden Promise; NIAB-78 cotton

(Pakistan); Rio Star grapefruit (USA).

Gene editing as a response to the off-target
problem of mutagenesis

Chemical mutagens as used in mutation breeding induce

mutations at a frequency ranging from once every 24 kb to

1000 kb (Spencer-Lopes et al., 2018). For example, EMS-induced

mutagenesis in common (hexaploid) wheat induced 104 779

SNPs throughout the genome (Hussain et al., 2018). While

mutagenized populations are good platforms for reverse genetics

(TILLING; Acevedo-Garcia et al., 2017), many back-crosses are

required to purify a specific desired mutation away from the

mutagenized background. In the last few years, genome editing,

a set of highly accurate tools for introducing specific genetic

variations, has been taken into use worldwide. CRISPR/Cas9 is

perhaps the best-known and most widely adopted example of

those tools (Hilscher et al., 2017). The development of genome

editing methods has been widely celebrated in the scientific

community for several reasons. As a research tool, they offer an

efficient platform for analysis of gene function through reverse

genetics. Moreover, they offer a means of knocking out a gene

whose function is known, in order to alter an associated crop trait

(Yin et al., 2017). Recently, the advent of base editing makes

possible the tweaking of gene function, in essence through the

creation of targeted allelic variation (Kim, 2018).

The issue of off-site mutations by CRISPR/Cas9, which together

with a lack of targeting is also the major drawback of chemical-

and radiation-based mutagenesis, has been given attention by

researchers. Editing experiments indicate that off-site mutations

are extremely rare or undetectable (Feng et al., 2018; Lee et al.,

2019), even if potential sites can be identified by software. Given

the low level of off-site mutations, back-crossing of the T0

generation will eliminate the secondary mutations with high

efficiency, unlike for conventionally mutagenized lines.

Allowing fishing by dynamite but forbidding fish hooks
and lures

Given the highly accurate nature of CRISPR/Cas9 -mediated

editing compared to conventional mutagenesis, why did the ECJ

take a laissez faire approach to varieties produced with the latter,

but subject genome-edited varieties to onerous regulation as a

GMOs? The ruling is equivalent to allowing fishing by dynamite

but forbidding fish hooks and lures. Although the Cas9 and guide

RNA (gRNA) construct is often transformed into plants during the

editing process, these can be segregated away in the T1 and

subsequent generations. Moreover, for vegetatively propagated

ª 2019 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd.
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crops and perennials, transgenesis-free methods have been

developed (Danilo et al., 2019). To understand why the ECJ

nevertheless regards edited plants as GMOs, regardless of the

presence of the construct, it is useful to look at the ruling. The

judgement of 25 July 2018 (Case C-528/16; http://curia.europa.e

u/juris/documents.jsf?num=c-528/162018) cites Directive 2001/

18 (https://eur-lex.europa.eu/legal-content/EN/ALL/?uri=celex%

3A32001L0018), which regulates GMOs, and applies the ‘pre-

cautionary principle’ for new approaches. However, 2001/18

excludes under its Annex 1B ‘certain techniques of genetic

modification which. . .have a long safety record’ and do not

involve recombinant DNA, in particular mutagenesis.

So how did genome editing as a mutagenesis method fall afoul

of the Court? The trouble appears to be a linguistic and logical

tangle over ‘modification’. Under 2001/18, a GMO is an organism

whose DNA has been altered ‘in a way that does not occur

naturally’. ‘Mutagenesis’ is excluded under 2001/18 if not

involving the use of a ‘genetically modified organism’. Now, the

Court finds that the editing techniques in particular alter DNA in

‘a way that does not occur naturally’ and therefore gener-

ate GMOs. This is because while Annex 1 A and Annex 1 B of

2001/18 include only recombinant methods in vitro or in vivo as

well as cell fusion as making GMOs, they do not explicitly exclude

mutagenesis because it is not included in the list not making

GMOs (e.g., in vitro fertilization, polyploidy induction). Moreover,

2001/18 held mutagenesis as a ‘technique of genetic modifica-

tion’, even if not leading to a GMO. So the Curia uses the original

confusions in 2001/18, whereby DNA can be modified but not

result in a genetically modified organism under law if the method

used had been ‘conventional’ with a ‘long safety record’. It holds

that the risks of new mutagenesis techniques possibly may be the

same as those of transgenesis, that the alterations are ‘unnatural’,

so therefore the precautionary principle holds and the new

methods must be regulated like transgenesis. Thus, the judges,

ignoring the science, forced genome editing under the outmoded

Directive 2001/18.

The idea that a technique, which uses a process found in

nature, is ‘unnatural’ is illogical. The idea that a single mutation

could pose risks, which the same mutation mixed in with a

thousand others does not pose, is nonsensical. The older,

scattershot methods introduce random changes throughout the

DNA, many of which remain in the final variety placed on the

market and have undetermined effects. In contrast, genome

editing is highly accurate and can only be undertaken with precise

knowledge of the target gene. Thus, it is a wonderment that the

ECJ ignored the statements of EU advice bodies, both the

Scientific Advice Mechanism (SAM) of the European Commission

and the European Food Safety Agency (EFSA), which held edited

plants to be equivalent to those produced by conventional means.

In contrast to the final EJC view, the preliminary ruling of EU

Advocate General Michal Bobek (http://curia.europa.eu/juris/d

ocument/document.jsf?text=&docxml:id=198532&pageIndex=

0&docxml:lang=EN) did suggest a channel by which genome-

edited plants might be outside the regulatory framework but

nevertheless GMOs. His opinion is based on two principles: first,

triggering of the precautionary principle must be based on broad

scientific data and not merely fear of risk; second, the definition

of mutagenesis cannot be fixed to its meaning at the turn of the

millennium, just as that of ‘vehicle’ or ‘means of communication’

cannot be restricted to their sense of two centuries ago, but

rather be adjusted to include newer approaches. Hence, like

conventional mutagenized lines, edited lines would outside the

regulatory framework of 2001/18, however, with the reservations

that new methods must ‘. . .not involve the use of recombinant

nucleic acid molecules or GMOs’. These caveats are very unclear,

because Bobek defines neither ‘involvement’ nor ‘recombinant’.

His view appears to differ from 2001/18 itself (Annex 1A Part 1

(1)), whereby the recombinant nucleic acids in regulated GMOs

must be ‘incorporated’ where they ‘do not naturally occur’ and

be ‘capable of continued propagation’. In any case, the EJC finally

maintained a premodern view of mutagenesis.

Response to the ECJ ruling

The response to the ruling among the worldwide scientific

community has been universally excoriating. The European Plant

Science Organisation (EPSO), representing 200 research institu-

tions from 30 countries and over 26 000 people working in plant

science, expressed disappointment and noted the lost opportuni-

ties for Europe. A consortium of 116 European research institu-

tions spearheaded by VIB/University of Ghent sent an open letter

to EC President Jean-Claude Juncker detailing their deep concern

over the downsides. A coalition of 13 countries from around the

world issued a statement at an autumn 2018 WTO meeting,

supporting policies that enable innovation by genome editing.

Consequences of the ruling

European Parliament and Council Directives need to be ‘trans-

posed’, that is, implemented in national law, for which the ECJ

ruling will cause no end of trouble. The ruling will be impossible

to enforce because edited plant varieties are indistinguishable

from ones derived from chemical or radiation mutagenesis or

from crosses to exotic germplasm. So Member States will find it

difficult to enforce laws based on Directive 2015/412, the

extension of 2001/18 that allows them to prohibit cultivation of

genetically modified crops on part or all of their territories. Two

cultivars with identical nucleotide changes, one made by editing

and the other not, neither with exogenous DNA, will need to be

separately regulated under the law. Foods that contain more than

0.9% GMOs should be labelled for sale in the EU; however,

edited ingredients will not be identifiable by their DNA. Foreign

producers in countries not regulating genome-edited crops as

GMOs (Table 1) have no legal responsibility to track or label

them; either all food products from such sources will need to be

banned, or the ruling will be meaningless. This has the potential

to raise serious international trade issues.

The decision by the ECJ is moreover simply bad policy for Europe.

Big agribusiness has the expertise and deep pockets to overcome the

regulatory hurdles of GMO legislation. In fact, the judgement gives

them an open playing field by restricting the entry of small players,

such as many breeders in Europe. Permission only to import a GMO

on average can cost €11 m–€16.7 m and take 6 years (https://
www.europabio.org/agricultural-biotech/faq/gmos-and-the-eur

opean-union/how-long-does-it-take-gm-crop-import-be-approved-

and-how-much-does-cost). Giventhat at least 15 gene-editedplants,

most from small players, had been developed by 2018 in the United

States alone (https://www.theparliamentmagazine.eu/articles/part

ner_article/europabio/how-europe-has-priced-out-innovation-exa

mple-plants), solutions to make crops more sustainable, healthy,

healthful and productive will be sought outside Europe. Statements

by several large breeders indicate that they will either breed edited

crops for markets outside Europe, move their editing research from

Europe, or both (https://european-biotechnology.com/up-to-date/

backgrounds-stories/story/cjeu-ruling-triggers-exodus-of-eu-plant-re

search.html). The growing list of countries (Table 1) that have either

ª 2019 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd., 1–3

Alan H. Schulman et al.2

http://curia.europa.eu/juris/documents.jsf?num=c-528/162018
http://curia.europa.eu/juris/documents.jsf?num=c-528/162018
https://eur-lex.europa.eu/legal-content/EN/ALL/?uri=celex%3A32001L0018
https://eur-lex.europa.eu/legal-content/EN/ALL/?uri=celex%3A32001L0018
http://curia.europa.eu/juris/document/document.jsf?text=&docxml:id=198532&pageIndex=0&docxml:lang=EN
http://curia.europa.eu/juris/document/document.jsf?text=&docxml:id=198532&pageIndex=0&docxml:lang=EN
http://curia.europa.eu/juris/document/document.jsf?text=&docxml:id=198532&pageIndex=0&docxml:lang=EN
https://www.europabio.org/agricultural-biotech/faq/gmos-and-the-european-union/how-long-does-it-take-gm-crop-import-be-approved-and-how-much-does-cost
https://www.europabio.org/agricultural-biotech/faq/gmos-and-the-european-union/how-long-does-it-take-gm-crop-import-be-approved-and-how-much-does-cost
https://www.europabio.org/agricultural-biotech/faq/gmos-and-the-european-union/how-long-does-it-take-gm-crop-import-be-approved-and-how-much-does-cost
https://www.europabio.org/agricultural-biotech/faq/gmos-and-the-european-union/how-long-does-it-take-gm-crop-import-be-approved-and-how-much-does-cost
https://www.theparliamentmagazine.eu/articles/partner_article/europabio/how-europe-has-priced-out-innovation-example-plants
https://www.theparliamentmagazine.eu/articles/partner_article/europabio/how-europe-has-priced-out-innovation-example-plants
https://www.theparliamentmagazine.eu/articles/partner_article/europabio/how-europe-has-priced-out-innovation-example-plants
https://european-biotechnology.com/up-to-date/backgrounds-stories/story/cjeu-ruling-triggers-exodus-of-eu-plant-research.html
https://european-biotechnology.com/up-to-date/backgrounds-stories/story/cjeu-ruling-triggers-exodus-of-eu-plant-research.html
https://european-biotechnology.com/up-to-date/backgrounds-stories/story/cjeu-ruling-triggers-exodus-of-eu-plant-research.html


excluded genome-edited varieties from GMO regulations or that

implement product- and not process-based regulations grows by the

month, leaving the EU increasingly isolated. Moreover, the paper-

work and delays imposed on academic research and field trials will

have a chilling effect, driving talent and innovation from Europe. In

sum, novel crops will be developed for growing conditions outside of

Europe by breeders outside Europe, with research and investment

likewise directed elsewhere. European food producers will fail to

receive locally sourced raw ingredients with improved and novel

qualities to meet public needs.

How forward?

Europe and the rest of the world face enormous agricultural

challenges. Meeting sustainable development goals for a popu-

lation of 9.7 billion projected for 2050 with less fertilizer, a fixed

water budget, on less land, and under a changing climate will

require novel cultivars as rapidly as possible. Genome editing is a

green solution, one of many tools that plant scientists, breeders,

and farmers desperately need now. As the 116-institution letter

to Juncker stated and EPSO likewise holds, the next Commission

must urgently prioritize the matter, and plants with small genetic

changes and no foreign genes must be outside of the regulatory

regime. Ultimately, EU GMO regulations urgently need updating

to a product-based and not method-based system. Current

mutation-derived crops are cultivated on tens of millions of

hectares. Likewise, edited varieties with targeted, knowledge-

based changes can help to provide a secure, economically and

environmentally sustainable food supply to all the world, should

the regulatory authorities choose to rely on evidence for their

decisions. Such crops are appearing outside Europe already; it is

time for Europe to bring the benefits of its research investment in

the plant sciences home.

Acknowledgements

A.H.S. acknowledges support under Natural Resource Institute

Strategic project 41007-00119800 and Academy of Finland

Decision 314961. We thank Dr. Diane Wray-Cahen, Foreign

Agricultural Service, United States Department of Agriculture, for

sharing information used in Table 1.

Author contributions

AHS conceived and wrote the manuscript; K-M.O-C and T.H.T.

contributed to the concept as well as to the writing of manuscript

and to critical revisions. All authors read and approved the final

manuscript.

Conflict of interest

The authors declare that they have no competing financial

interests.

References

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resistance in hexaploid bread wheat generated by a non-transgenic TILLING

approach. Plant Biotechnol. J. 15, 367–378.

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Table 1 Current regulatory status of plant genome editing for

selected countries outside the EU

Region/

country

Current genome editing

status

Example products in market

pipeline

North America

Canada Product-, not technology-

based.

USA Not GMO At least 20 products, including

high-oleic-acid soy oil; high-

fibre wheat; alfalfa; cold-

storable potato; reduced-

browning potato; coeliac-

friendly wheat; maize with

waxy starch

South America

Argentina Not GMO At least 10 pending plant

varieties

Brazil Not GMO Cacao

Chile Not GMO

Columbia Not GMO Micro-Tom tomatoes

Honduras Not GMO

Paraguay Not GMO

Uruguay Expected to harmonize with

other South American

countries

Other

Australia Editing without template

not regulated as GMO

Israel Not GMO if no transgene

Japan Not GMO

New

Zealand

GMO

Norway Not regulated as GMO if

change can occur by

conventional methods

Philippines Not GMO

Russia New decree exempts GE

crops from GM regulations

Switzerland Draft revision to GMO law

expected 2019

ª 2019 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd., 1–3

A future for genome-edited crops in Europe? 3