World Agriculture Vol 6 Issue 1 2016 by Script Media

editors

World Agriculture Editorial Board Patrons Professor Yang Bangjie Member of the Standing Committee of the National People’s Congress of China. (China) Lord Cameron of Dillington Chair of the UK All Party Parliamentary Group for Agriculture and Food for Development. (UK) Maxwell D. Epstein Dean Emeritus, International Students and Scholars, University of California, Los Angeles. (USA) Sir Crispin Tickell GCMG, KCVO, formerly, British Ambassador to the United Nations and the UK’s Permanent Representative on the UN Security Council (UK) Managing Editor and Deputy Chairman Dr David Frape BSc, PhD, PG Dip Agric, CBiol, FRSB, FRCPath, RNutr Mammalian physiologist Regional Editors in Chief Robert Cook BSc, CBiol, FSB. (UK) Plant pathologist and agronomist Professor Zhu Ming BS, PhD (China) President of CSAE & President of CAAE Scientist & MOA Consultant for Processing of Agricultural Products & Agricultural Engineering, Chinese Academy of Agricultural Engineering Deputy Editors Dr Ben Aldiss BSc, PhD, CBiol, MSB, FRES. (UK) Ecologist, entomologist and educationalist Dr Sara Boettiger B.A. ,M.A.,Ph.D (USA) Agricultural economist Professor Neil C. Turner FTSE, FAIAST, FNAAS (India), BSc, PhD, DSc, (Australia) Crop physiologist Professor Xiuju Wei BS, MS, PhD (China) Executive Associate Editor in Chief of TCSAE, Soil, irrigation & land rehabilitation engineer

Published by Script Media, 47 Church Street, Barnsley, South Yorkshire S70 2AS, UK

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Members of the Editorial Board Professor Gehan Amaratunga BSc, PhD, FREng, FRSA, FIET, CEng. (UK & Sri Lanka) Electronic engineer & nanotechnologist Professor Pramod Kumar Aggarwal B.Sc, M.Sc, Ph.D. (India), Ph.D. (Netherlands), FNAAS (India), FNASc (India) Crop ecologist Dr Andrew G. D. Bean BSc, PhD, PG Dip. Immunol. (Australia) Veterinary pathologist and immunologist Professor Tim Benton BA, PhD, FRSB, FLS Food systems, food security, agriculture-environment interactions Professor Phil Brookes BSc, PhD, DSc. (UK) Soil microbial ecologist Professor Andrew Challinor BSc, PhD. (UK) Agricultural meteorologist Dr Pete Falloon BSc, MSc, PhD (UK) Climate impacts scientist Professor Peter Gregory BSc, PhD, CBiol, FSB, FRASE. (UK)

Soil scientist Professor J. Perry Gustafson BSc, MS, PhD (USA) Plant geneticist Herb Hammond (Canada) Ecologist, forester and educator Professor Sir Brian Heap CBE, BSc, MA, PhD, ScD, FSB, FRSC, FRAgS, FRS (UK) Animal physiologist Professor Fengmin Li BSc, MSc, PhD, (China) Agroecologist Professor Glen M. MacDonald BA, MSc, PhD (USA) Geographer Professor Sir John Marsh CBE, MA, PG Dip Ag Econ, CBiol, FSB, FRASE, FRAgS (UK) Agricultural economist Professor Ian McConnell BVMS, MRVS, MA, PhD, FRCPath, FRSE. (UK) Animal immunologist Hamad Abdulla Mohammed Al Mehyas B.Sc., M.Sc. (UAE) Forensic Geneticist Professor Denis J Murphy BA, DPhil. (UK) Crop biotechnologist Dr Christie Peacock CBE, BSc, PhD, FRSA, FRAgS, Hon. DSc, FSB (UK & Kenya) Tropical Agriculturalist Professor R.H. Richards C.B.E., M.A., Vet. M.B., Ph.D., C.Biol., F.S.B., F.R.S.M., M.R.C.V.S., F.R.Ag.S. (UK) Aquaculturalist Professor Jacqueline Rowarth PhD, CNZM, CRSNZ, FNZIAHS (New Zealand) Agricultural Economist Professor John Snape BSc PhD (UK) Crop geneticist Professor Om Parkash Toky MSc, PhD, FNAAS, (India) Forest Ecologist, Agroforester and Silviculturist Professor Mei Xurong BS, PhD Director of Scientific Department, CAAS (China) Meteorological scientist Professor Changrong Yan BS, PhD (China) Ecological scientist Advisor to the board Dr John Bingham CBE, FRS, FRASE, ScD (UK) Crop geneticist Editorial Assistants Dr. Zhao Aiqin PhD (China) Soil scientist Ms Sofie Aldiss BSc (UK) Rob Coleman BSc MSc (UK) Michael J.C. Crouch BSc, MSc (Res) (UK) Kath Halsall BSc (UK) Dr Wang Liu BS, PhD (China) Horiculuturalist Dr Philip Taylor BSc, MSc, PhD (UK)

In this issue ...

First issue contents

notice:

n World Agriculture welcomes your comments, criticisms and discussions

editorials: Number 1 n Our publications for the 4-5 Spring of 2016 emphasise the role of technology for small farmers and of “smart villages” in developing countries. Are the European Union Regulators Laggards? Number 2 n Biotech For Food, 6 Acceptance And Rejection. Has the day of Agribiotec arrived? Professor Sir John Marsh

If you wish to submit an article for consideration by the Editorial Board for inclusion in a section of World Agriculture: a) Scientific b) Economic & Social c) Opinion & Comment or d) a Letter to the Editor please follow the Instructions to Contributors printed in this issue and submit by email to the Editor editor@world-agriculture.net Published by Script Media, 47 Church Street, Barnsley, South Yorkshire S70 2AS, UK

Number 3 n India: Potential based on tradition Robert Cook

scientific: Number 4 n Has agricultural biotechnology finally turned a corner? Professor Denis Murphy

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editorials

World Agriculture welcomes your comments, criticisms and discussions

ur journal is to open a new section entitled “Readers’ Comments, Criticisms, Opinions and Letters”. The objectives of this section of the Journal is for unedited views to be expressed and discussed amongst our readers. Your comment emailed to the Editor (editor@world-agriculture. net) could be published within a week

or two, so that our readers are able to participate in any current international debate concerning agricultural production in the environment, or to comment on any article we have published. Owing to space limitation it may be necessary to abridge some longer comments; but so long as the statement does not break any law it could be

selected for publication- similarly to Letters to the Editor of a newspaper. As is the practice with other Publications please send your comment together with your full name, postal address and telephone number to the Editor (editor@world-agriculture.net). If it is your wish your name and the country of your address, only will be published. Editor, April, 2016.

Our publications for the Spring of 2016 emphasise the role of technology for small farmers and of “smart villages” in developing countries

Are the European Union Regulators Laggards?

It is appropriate, first, to review the discussions and outcome of a meeting of the FAO in Rome, 15-17 February this year. The meeting was entitled “The Role of Agricultural Biotechnologies in Sustainable Food Systems and Nutrition”. The key question at the meeting was: to what extent could agricultural biotechnologies assist and benefit smallholders in developing sustainable food systems and improve nutrition during climate change Our review, by Prof. Denis Murphy, who chaired one of the sessions, concentrates on the enormous and rapid advances which are being made in the technology of plant and animal breeding. Murphy (in this Issue) describes the advances in methodology. These developments make the distinction difficult to detect between genetic manipulation, by so-called GM techniques and those by conventional techniques, or even with those hybrids which occur naturally. In some cases the distinction does not exist. As a consequence the EU regulations for the approval of new

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Fig. 1. World map of arable land, percentage by country in 2006 (1) gene editing should not be characterised cultivars are outmoded, particularly as as GMOs. many countries have already approved Gene editing can considerably widen and used techniques, developed in the the range of traits, especially smallholderEU, for which the Regulators in the EU relevant traits, in hitherto disregarded have not yet given their approval. crops and these will be altered much Murphy concludes with the statement more rapidly and cheaply than was that the use of genome editing and previously possible. genomics technologies has the scope There is an urgent need to accelerate to vastly increase crop yield, quality capacity building in all forms of agbiotech and biodiversity. These new genetic and related public outreach in all technologies may eventually make much countries. of the current ‘conventional’ GM-based This provides a great opportunity for crop improvement and its risk assessment the emergence of a new generation of & regulation obsolete and there are innovative public-private partnerships and already calls that organisms altered by

new agbiotech methods aimed specifically at improving smallholder agriculture, as we face up to increasing food security challenges across the world. Murphy further argues there is a case for the FAO to coordinate an investigation into the feasibility of developing opensource biotechnologies (especially genome editing) to be used for publicgood applications in developing countries. Urgency, is of the essence, as climatic adaptation of crops is essential if yields of healthy crops are not only to be sustained, but increased. The world’s cultivatable areas are not increasing (total <14 x 106 km2), whilst the climate is changing and the population to be fed is increasing. In the case of a number of countries, e.g. Brazil, the area is being maintained, or increased, at the

expense of natural forest. The proportion of cultivatable land in India exceeds 40% of the total land area (Fig. 1), a country whose population is increasing rapidly and where climate change is likely to have one of the largest impacts. Murphy’s paper will be followed, in due course and most appropriately, by two papers from India by Professor Toky and co-workers covering details of innovative agroforestry for livelihood and environmental security, especially for small-holders. These papers provide details of tree species they recommend for use under a variety of Indian environments. Shortly after this we shall publish a paper by Tang Huaizhi et al. on how China is using current technology in

editorials

farmland development and a second by Wang Jing and co-workers, giving evidence of how the Chinese are enhancing the fertility and increasing the crop yields of a large area of arid salinealkali land in the Ningxia Hui Region. Finally this spring we shall publish another Indian paper in which Professor Aggarwal and Dr Chhetri, outline the development of smart villages in South Asia. Each of these contributions will be accompanied by editorial comments.

References

1. “The CIA World Factbook”. Central Intelligence Agency. Retrieved June 2006. Percentage shares of total land area [by country] used for arable land – land cultivated for crops like wheat, maize, and rice that are replanted after each harvest.

David Frape

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editorials

Biotech for food, acceptance and rejection Has the day of Agribiotec arrived?

urphy’s paper, which reports on The FAO Symposium on agbiotech, February 2016, provides evidence of changes in the use of agricultural biotechnology, reports on a number of case studies in the use of GM in developing countries and discusses the future role of this unfolding technology and the contribution it may make to secure food supplies. The substance of the discussion is that the traditional model of GM as a tool by which big transnational companies dominated the world is clearly untrue. In a variety of Public Private Partnerships, the technique has offered substantial gains to small holders. Through Public research agencies focus is directed on the potential for social benefit as well as economic gain. Through genome editing new, improved plants are made available. In some cases there may be no residual evidence that genetic tools have been used, making current testing regimes irrelevant. Agricultural biotechnology is already widely used to enhance productivity and resilience as well as to reduce the use to insecticides and herbicides. This benefits both food security and environmental conservation. In a world facing a remorseless rise in population and an ever greater challenge from climate change this is desperately needed good news. The hostility of much of Europe to the use of methods that offer so much prompts questions about the application of science, especially in relation to the food system. There are many involved issues among them: Distrust of the ‘expert’: If it works, why fix it? The social cost of economic restructuring: Externalities associated with new and old methods. New science involves grappling with

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ideas with which we have no familiarity. In coming to grips with what it offers we have to rely on ‘experts’. An expert is someone who knows more about a specific issue than most other people. It is important to recognise that they do not know everything and inevitably as science advances their evidence may prove to be wrong. (Misguidedly this enables people, who for whatever reason, prefer not to employ reliable evidence in their decision processes, to reject innovations based on it). In effect we often prefer an emotionally made decision to trying to understand the problem. The complexity of this distrust is greatly increased because in reality the analysis of almost every innovation demands expertise in a number of dissimilar areas – social, economic, philosophical as well as of the native science from which the new product emerges. As a result people with a variety of interests to defend find it easy to produce rival experts, to challenge the clarity of the original proposal for a new product or method. Every innovation involves risk. A standard response from those whose current situation is comfortable, is ‘If it works, don’t fix it”. Experience with helpful computer experts who promise to iron out minor muddles resulting from miss-use seems to confirm this. The logical problem here is the refusal to accept that failure to adapt is itself a major risk. Europe has been comfortable with an assured food supply from native sources plus low cost imports. However, in the long term the failure to adapt new, more efficient production systems could destroy the industry. Exports would demand ever-growing subsidies; imports would displace home production on grounds of suitability for purpose and price, assuming we accept the

Professor Sir John Marsh

production technology. The risks of inertia are unseen but enormous. New methods imply restructuring traditional industries. GM technology may make redundant historical ways of controlling pests and diseases. This is painful for existing producers and their communities. For the suppliers of such inputs capital may become worthless and existing jobs disappear. Major changes, such as these have impacted on European agriculture. As a result established or traditional communities lost their economic rationale. Economic calculation may Indicate that the overall benefit to society of making a change is so large that all ‘losers’ could be fully compensated for any loss of income. In practice such aids to change are seldom supported. Additional social security payments for those who lose jobs or businesses become necessary but are resisted whilst the recipients may be seen as idle or incompetent. Faced with this reality those who feel threatened by new methods have little choice but to resist them. All economic activities involve social costs and benefits. Some of these will figure within the accounts of the firms concerned however, many do not. Prominent among these are changes in the impact of economic activity on the natural environment, changes that have costs not only for those who enjoy prized amenities in (and of) the countryside but also in such benefits as controlled water supplies, waste disposal and clean air. New technologies challenge the status quo and are instinctively rejected. Developments in the science and application of biotechnology may well suggest it has turned one corner in gaining acceptability. The reality of political decision taking suggests that as it does so, it will encounter others.

editorials

India: Potential based on tradition

nyone who has visited India two or three times in the last decade cannot fail to be impressed by the huge economic progress made in recent years. Dual carriageways and regular flights now link most major cities and traffic becomes more frenetic by the day, as new cars, motor cycles and lorries crowd onto the congested roads. This is a reflection not just of economic activity, but of increasing affluence, especially amongst an expanding middle class, whose spending power provides benefits throughout the country. India is now a major global power. Although the population continues to increase there is evidence that the rate is decreasing with the latest census showing a drop in the number of under 20s in all communities (3). Such an effect would be expected if the trends observed in other countries are followed, where increased economic activity and education are associated with reduced overall birth rates. In India, the trend is also encouraged by government policy. There are of course great challenges. India still has a large number of cultural, linguistic and ancestral communities whose interests need to be recognized and supported in a changing country, where their needs may not always be met by vigorous pursuit of a market economy. As pointed out by Frape (this issue) 40% of Indiaâ&#x20AC;&#x2122;s land area is devoted to arable production for food to meet the nutritional requirements of the growing population. About 24% of the land area is forest (2) and 9% is managed as national park or wildlife sanctuary. These areas are a vital buffer to preserve Indiaâ&#x20AC;&#x2122;s wildlife and preserve iconic species such as the threatened tiger and the Asian lion. The population of the latter is increasing in the Gir Forest in Gujarat, thanks to the skilful management of the Gujarat Forest Service in cooperation with the National Parks Service and local communities. Likewise, Siriska wildlife sanctuary in Rajasthan, a semiarid state, has been repopulated with Bengal tigers. This is a success story of tiger conservation in an area where large scale human interference had eliminated them. Open wildlife sanctuaries also play an important role in conservation.

Robert Cook and Professor Parkash Toky

For example, the Bisnoi community in north India protect wildlife in their agricultural fields and conserve many species including black buck (a rare antelope). Sanctuaries of this type are an important component of protection for flora and fauna. As in all countries, the challenge is to maintain food production from a decreasing land area whilst preserving territory for biodiversity when an increasing middle class requires greater attention be given to wilderness preservation and wildlife sanctuaries. Returning European visitors to Indiaâ&#x20AC;&#x2122;s wildlife sanctuaries and national parks will have noticed how, in recent years, numbers of Indian visitors have overtaken those from other countries; a sign of increasing concern for conservation as well as increasing affluence in India itself. These changes are all likely to be influenced by the challenges of climate change. Unseasonal variation in the usually predictable climate of northern India seems to be especially serious this year. After two years of low monsoon rainfall, a warm and dry winter has reduced plantings of the essential winter crops of rice and oilseeds by over 4%, and by 7% for wheat alone (3). These figures represent a significant shortfall in production. Temperature rises, rainfall changes and sea level rises have already affected India to a significant extent since the 1950s, compounding an already variable climate. The 5th IPCC report (4) indicates that these trends will continue so there will be increased risk of flooding with more variable rainfall and increased temperatures which will reduce yields of rice and wheat in particular. This puts India at the forefront of global challenges for adaptation to climate change and the need to adopt new agricultural technology to increase yield per unit area and thus production efficiency. Cotton is an excellent example of this, where adoption of GM cultivars in recent years has increased productivity by 55% since 2000 and increased farmer profits by 50% (6). Murphy (1) identifies other crops which have the potential to effect similar yield improvements. Adequate field testing of these will be essential if their potential is to be realised, according to a leading crop scientist, M S Swaminathan (7).

The environmental lobby however, considers GM crops to be unsafe for the human and animal consumption (despite much evidence to the contrary), and not sustainable in the long term. They claim the quality of GM foods is inferior to so called natural foods. They also claim repeated application of the same herbicide reduces biodiversity and stability of the ecosystem. Small scale farmers, especially in marginal areas contribute significantly to Indian agriculture. With changing climate and increased risk of crops failures, these farmers are less likely to afford the high seed cost of new crops and rely on farm saved seed. They frequently have one or two buffaloes, cows or goats which provide resilience in times of crop failures. This small scale agriculture, so important in India, relies on diversity of foods from a small area of land and may well be more resilient in times of unpredictable weather. The Indian civilization has survived for thousands of years and developed on the basis of a rich cultural tradition to become a global powerhouse. The nation demonstrates the challenges facing the globe, as societies increase in affluence they become more conscious of their heritage. Historically, such resilience has helped India survive prolonged famines and human invasions; the rich heritage and diversity of plants and animals helped man to survive. Articles in recent issues of World Agriculture and planned for our next issue highlight how India can meet these challenges with confidence.

References

1. Murphy, D (2016). Title to be decided. World Agriculture 6.3 2. Anon (2016). National Parks, Wildlife Sanctuaries and Biosphere Reserves in India http://ces.iisc.ernet.in/envis/sdev/parks.htm Retrieved 3 April 2016 3. Miscellaneous reports in The Times of India, January 2016 4. Anon (2014) http://cdkn.org/wp-content/ uploads/2014/04/CDKN-IPCC-Whats-in-it-for-SouthAsia-AR5.pdf Retrieved 3 April 2016 5. Anon (2016) http://www.cotcorp.gov.in/nationalcotton.aspx#indiancotton Retrieved 4 April 2016 6. Vaidyanathan, G (2012) Genetically modified cotton gets high marks in India: Engineered plants increased yields and profits relative to conventional varieties. http://www.nature.com/news/genetically-modifiedcotton-gets-high-marks-in-india-1.10927 Retrieved 4 April 2016 7. Vishwa, M (2016) Test GM crops at University farms for fair verdict. Times of India, January 13 2016

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Has agricultural biotechnology finally turned a corner?

Report of FAO Symposium on genetic manipulation as used in agriculture, Rome, February, 2016

Denis J Murphy1 and Ivar Virgin2 1. Professor of Biotechnology and Head of the Genomics & Computational Biology Group, University of South Wales, CF37 4AT, United Kingdom, Email: denis.murphy@southwales.ac.uk 2. Senior Research Fellow at Stockholm Environment Institute, Stockholm, Sweden, Email: ivar.virgin@sei-international.org

Summary

Agricultural biotechnology, or agbiotech, involves a suite of technologies that include not only GM (genetic manipulation/ modification), but also many other non-GM methods. Over the past three decades, agbiotech has been largely equated in the minds of many people with the introduction of GM crops and the ensuing public controversies, particularly in Europe. This situation may now be about to change as non-GM biotechnologies such as marker-assisted selection and targeted mutagenesis are increasingly used in crop breeding. In addition, the very recent advent of genome editing technologies is blurring the distinction between what can or should be categorised as either GM or non-GM. The new genome editing technologies are also considerably cheaper, faster and easier to deploy than conventional GM methods, many of which date from the 1980s and 1990s. Some of the new biotechnologies may also be less subject to IPR (intellectual property rights) restrictions and therefore more widely available for application to commercial subsistence crops. Finally, there are increasing indications that developing countries around the world are producing their own biotech crops (including GM cultivars) for the benefit of their own farmers. It can be argued, therefore, that agbiotech may have turned a corner and is now emerging as a more diverse and increasingly vital set of dynamic tools for global crop improvement. Key words: biotechnology, developing countries, smallholders, Food and Agriculture Organization, genetic modification, markerassisted selection, genome editing, brinjal/eggplant, advanced breeding, genomics Abbreviations: CRISPR Clustered, Regularly Interspaced, Short Palindromic Repeats; FAO Food and Agriculture Organization; GM genetic manipulation/modification; IPR intellectual property rights; PPP Public-Private Partnership; QTL Quantitative Trait Loci; TALENs Transcription Activator-Like Effector Nucleases. Glossary: Orphan crop, A crop which has been relatively neglected in terms of modern breeding activities; this term applies to many staple crops in developing countries.

Policy proposals

n Governments, NGOs and other civil society representatives should engage in a comprehensive public debate on how advances in agbiotech, can benefit smallholders in developing countries by producing more sustainable food systems and improving nutrition in view of changing climate and resource scarcity. In particular genome editing in crop and livestock improvement should be accommodated. n Governments across the world should urgently address the issue of how biotech-derived crops are regulated, especially in view of recent developments in genome editing for crop and livestock improvement n A public sector led initiative, possibly coordinated by FAO, should be set up to investigate the feasibility of developing open-source biotechnologies (especially genome editing) for use in public-good

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applications in developing countries. n Increasing support should be given to Public Private Partnerships (PPPs) to increase agbiotech innovation. This would include support for the public R&D sector, particularly in developing countries, where there is enormous scope for adaptation of bioscience advances. It would also mean more support, not the least with incubation services, for PPPs to target low profit markets with high social impact, so contributing to sustainable development.

Introduction

gricultural biotechnology, or agbiotech, encompasses a diverse range of biologically based methods that have been applied to agricultural improvement since the beginning of modern scientific breeding in the early 20th century (1). As we move through the second decade of the 21st century, we face considerable challenges such as population growth,

food insecurity, climate change, fresh water scarcity, and the emergence of new pests and diseases (1,2). It is therefore more important than ever that we are able to use these biological tools to increase the yield and quality of our crop and livestock resources. It is also vital that this goal is achieved in a manner that is both environmentally appropriate and sustainable in the long term, especially in the context of the requirement for continued intensive food production by future generations (2). Agbiotech is often equated with so-called GM (genetic manipulation) technologies. However, many bio-based technologies were being widely used in agriculture long before the first GM bacteria were created in the 1970s, or the first GM plants in the 1980s Examples of such lab-based, but nonGM, biotechnologies include the use of tissue culture for micropropagation, the creation of hybrid plants between and within species (e.g. via embryo rescue), the manufacture of doubled haploids,

scientific and the use of induced mutagenesis involving chemicals or radiation to create novel crop phenotypes. Other examples include use of fermentation to modify foods, DNA markers to select suitable variants in large populations, and reproductive technologies such as cloning. None of these biotechnologies are legally defined as ‘GM’ and most of them have been used without controversy for many decades (3). Interestingly, GM methods are now used routinely and without controversy in a host of medical applications, such as the production of life-saving recombinant therapeutic products including human insulin and blood clotting factors. In contrast, however, the use of GM technologies in agriculture has caused substantial (if arguably unwarranted) public concern. This has, to some extent, tarnished the entire field of agricultural biotechnology, especially in some parts of Europe where field trials of new crop cultivars are sometimes still subject to vandalism by anti-GM campaigners. In this context, it was telling that at a high level conference on agbiotech convened in Mexico in 2010 by the United Nations Food and Agriculture Organization, only one European country (The Netherlands) bothered to send a delegation. In contrast, dozens of developing country delegations attended as well as other major food-exporting nations such as Canada and the USA (4). At the time a group of European agricultural scientists expressed their concerns as follows: “We wish to express our concern and dismay at the apparent lack of intergovernmental engagement by European governments regarding the proven positive roles of modern biotechnologies as key tools supporting efforts to address the issue of food security, especially in developing countries. This was shown clearly by the failure of 26 of the 27 members states of the European Union to send any official government delegations to participate and engage in the recent United Nations Food and Agriculture Organization (FAO; Rome) intergovernmental conference (ABDC10) on ‘Agricultural biotechnologies in developing countries’ (http://www.fao. org/biotech/abdc/en). The Netherlands was the only EU member state to send an official government delegate to ABDC-10.” (4) Indeed, over the past twenty years since the first large-scale releases

Figure 1. Plenary session of FAO Symposium on Agricultural Biotechnologies agbiotech, February 2016. Picture courtesy of FAO. of GM crops took place in the USA in 1996, there has been a distinct scepticism about agbiotech, and especially GM crops, in Europe. This scepticism was also manifested in some developing countries where GM crops have been regarded in some quarters as foreign threats to indigenous crops or even as evidence of a neo-colonialist drive by a few multinational corporations to take over the food chain (5,6). In a few cases, much needed food aid was rejected in Africa, simply because it included GM crop products from the USA that were regarded with unwarranted suspicion by local politicians (7). In this article, we argue that there are now signs of significant changes in global attitudes to agbiotech that have emerged as a result of increasing engagement by developing countries. This has been coupled with some dramatic advances that have the potential to democratise the use of these technologies. Indeed it can be argued that agbiotech has recently made decisive strides in terms of its broad utility, practicality, and public acceptability across much of the world. Unfortunately, however, awareness of these developments in Europe continues to lag behind much of the rest of the world and the region is in danger of becoming a backwater in the application of some forms of modern agriculture. These fears are also addressed by a report by the European Academies Science Advisory Council (EASAC) (8). EASAC makes the point that owing to stifling regulations countries in Europe, limited R&D funding and innovation

investments in agbiotech. This made these countries unable to fully use the advances of modern biosciences to develop more productive, resource efficient and climate smart agricultural systems.

The FAO Symposium on agbiotech, February 2016

From 15-17 February, 2016, some 400 scientists, government officials, private sector and civil society representatives gathered at the headquarters of the United Nations Food and Agriculture Organization in Rome to discuss “The Role of Agricultural Biotechnologies in Sustainable Food Systems and Nutrition” (9). This landmark symposium was a follow up from the FAO agbiotech meeting in Mexico in 2010 (see Introduction above). The key question at the 2016 meeting was to discuss to what extent agricultural biotechnologies could assist and benefit smallholders in developing sustainable food systems and improving nutrition in the context of climate change. The meeting was also a forum for discussion of new developments in the creation of new biotechnologies and the practical implementation of existing biotechnologies in countries ranging from Bangladesh to Brazil. As stated in the plenary session by José Graziano da Silva, DirectorGeneral, FAO, “Given the magnitude of the challenge, we must use a broad portfolio of tools to fight malnutrition and achieving sustainable agriculture”. It was repeatedly emphasized by participants that agbiotech should

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be regarded as a large and rapidly expanding toolbox of bioscience technologies, ranging from controversial and fast evolving techniques, such as genome editing and conventional genetic modification (GM) to less controversial techniques such as mutagenesis and tissue culture (non-GM technologies). As stated on the FAO website: â&#x20AC;&#x153;The international symposium will explore how the application of science and technology, particularly agricultural biotechnologies, can benefit smallholders in developing sustainable food systems and improving nutrition in the context of climate change. The symposium takes a multisectoral approach, covering the crop, livestock, forestry and fishery sectors. It also aims to cover the wide spectrum of available biotechnologies, including microbial food fermentation, tissue culture in plants, reproductive technologies in livestock, use of molecular markers, genetic modification and other technologies.â&#x20AC;? Although there were some delegates who disputed the relevance of agbiotech for small farmers and who continued to stress the corporatist origins of GM technologies, it was striking that most developing country delegates were firmly in favour of the use of agbiotech for the improvement of both crop and livestock husbandry. This was especially true for delegates from Africa where the past few years have witnessed the release of numerous biotech-improved crop cultivars that were developed using both GM and non-GM technologies. In the next section of this article, three case studies on uptake of agbiotech in developing countries that featured at the symposium will be presented. For interested readers, the complete Powerpoint presentations from the meeting are available at: http://www.fao.org/3/a-bc787e.pdf and most of the verbal presentations are also available as webcasts at: http://www.fao.org/about/meetings/ agribiotechs-symposium/webcasting/ en/.

extent that this once famine-prone and overcrowded nation is now selfsufficient in key staple crops such as rice (10, 11). In her presentation to the FAO Symposium, Begum Matia Chowdhury, the long-serving Minister of Agriculture in Bangladesh, outlined some of the impressive recent achievements in her country and especially the introduction of a cultivar of GM brinjal (also called zucchini or eggplant) that is engineered to be tolerant to attack by certain insect pests. This was achieved through the expression of the naturally occurring bacterial insecticide Bt in the brinjal plant. The Bt insecticide originates from Bacillus thuringiensis, which is a soil bacterium that produces so-called Bt proteins that are toxic to certain groups of insects. To date, researchers have taken the gene(s) encoding one or more of the >30 Bt toxins and introduced them into crops such as soybean and cotton to produce cultivars that can protect themselves from larval attack. While there have been several examples of widespread smallholder adoption of GM cash crops, most notably Bt cotton in India and Africa, several promising subsistence GM crop candidates have faced lengthy delays. However, as noted by Begum Chowdhury, Bangladesh approved Bt brinjal/eggplant for planting in 2013 (12). In 2014 commercialization was initiated via a Public-Private Partnership (PPP) when a total of 120 farmers planted 12 hectares. This followed strong political support from the government, with leadership from Ministry of Agriculture, and close

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collaboration with farmer groups and private sector breeders. Despite the expected adverse publicity from anti-GM campaigners, the introduction of Bt brinjal in Bangladesh appears to have been a qualified success, decreasing the use of chemical insecticides, and improving crop productivity and farm profitability (13). This approval of GM Bt brinjal by Bangladesh is important in that it has broken the impasse experienced in trying to gain approval for commercialization of the introduction of the same crop in India and the Philippines. It also serves as a possible model for other small poor countries. Two other developing countries in Asia, Vietnam and Indonesia, also approved cultivation of GM crops in 2014 for commercialization in 2015 (14). Vietnam approved Bt maize and Indonesia approved a drought tolerant sugarcane for food, whilst approval for feed is pending; 50 hectares of sugarcane were planted in 2014 for planned commercialization in 2015. In 2014, it is estimated that approximately 18 million farmers grew GM crops, about 90%, or 16.5 million, were small farmers in developing countries. In addition to economic gains, farmers benefited enormously from at least a 50% reduction in the number of insecticide applications, thereby reducing farmer exposure to insecticides, and importantly it contributed to a more sustainable environment and better quality of life. It is noteworthy that many of these

Case studies on uptake of agbiotech in developing countries 1. Brinjal in Bangladesh: breaking the impasse on GM crop acceptance? Over recent decades, Bangladesh made enormous strides in the use of modern agricultural practices to the

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Figure 2. Bt brinjal being grown by smallholders in Bangladesh. Picture courtesy of Mark Lynas.

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Figure 3. Begum Matia Chowdhury, Minister of Agriculture, Bangladesh addressing the FAO Symposium on Agricultural Biotechnologies about some of the impressive achievements in her country, which is now selfsufficient in key staple crops such as rice (9, 10). Picture courtesy of FAO. GM crops were introduced via PublicPrivate Partnerships (PPPs) rather than being simply for-profit ventures by global multinational corporations. The importance of PPPs in the roll out of new crop cultivars has been discussed in recent reports from FAO (15) and the Joint Research Centre of the European commission (16). 2. EMBRAPA in Brazil: PPP-led GM crop development EMBRAPA (Empresa Brasileira de Pesquisa Agropecuária or the Brazilian Agricultural Research Corporation) is the major public sector agricultural R&D organization in Brazil. With an annual budget of US$1 billion, EMBRAPA has been especially active in fostering PPPs in agbiotech. EMBRAPA is also one of the few public bodies in the world to have a long term programme for development and commercialisation of GM crops. It initially focused mainly on soybeans, which are now grown by millions of Brazilian farmers ranging from smallholders to large international combines. In 2014, Brazil commercially planted GM soybeans with insect resistance and herbicide tolerance on 5.2 million hectares (Mha). This was a substantial increase from 2.2 Mha in 2013 (14). The expansion of soybean production in Brazil has been a driver of economic growth and increased farm incomes, although it has also been widely discussed in terms of its putative environmental impact (17, 18). More recently EMBRAPA has further widened the scope of its GM crop

portfolio. In 2015, it gained approval to commercialize a locally developed cultivar of pinto beans with resistance to the devastating golden mosaic virus, planned for release in 2016. EMBRAPA has also developed a novel herbicide tolerant soybean via a PPP with BASF. This new soybean cultivar is currently awaiting EU import approval prior to planned commercialization later in 2016 or 2017. EMBRAPA is also developing GM folate-fortified lettuce and drought resistant sugarcane (14). EMBRAPA is an example of a large state enterprise that has taken the lead in innovative biotech crop development, with PPP engagement where appropriate. While it was initially focused mainly on the major commercial crop, soybean, EMBRAPA has now started to produce GM crops aimed more at smallholders and internal markets rather than commodity crops for export. 3. Emergence of agbiotech PublicPrivate Partnerships (PPPs) in Africa Over the past decade there have been numerous PPP ventures in Africa that have focused on both GM and non-GM crops aimed at smallholders (19, 20). For example, Cameroon, Egypt, Ghana, Kenya, Malawi, Nigeria, and Uganda have deployed agbiotech breeding tools and conducted field trials on the following broad range of staple crops (2): rice, maize, wheat, sorghum, bananas, cassava, and sweet potato (orphan crops include many developing country staples that have been relatively neglected in terms

of modern breeding activities). African GM crops are often the result of major PPP efforts that include development of cultivars with increased drought tolerance, better storage properties, improved disease resistance and nutritional characteristics, such as biofortfied cassava. These crops are of great interest to small-scale farmers and also for the food insecure. Despite their obvious benefits, it will take many years for these GM crops to reach small-scale farmers because of the regulatory hurdles, inefficient technology dissemination pathways and weak seed markets. The Water Efficient Maize for Africa (WEMA) is, however, expected to deliver its first GM drought tolerant maize with Bt insect resistance in South Africa as early as in 2017, followed by Kenya and Uganda, and then by Mozambique and Tanzania, subject to regulatory approval (21). Bt cotton is grown at a commercial scale in South Africa, Burkina Faso and Sudan. In 2015 there was an apparent setback to GM crop cultivation in one African country when Burkina Faso announced that it would be starting a phased reduction of Bt cotton cultivation (22-24). The cultivar had been developed by Monsanto and its introduction was strongly backed by the government of Burkina Faso. The crop had been popular among farmers as it was less labour intensive and required fewer inputs than conventional cotton. Cotton yields were good but it turned out that the Bt cotton cultivar used produced fibre that was traded at a discount to that of other West African origins so the cotton processors had reduced incomes (24). The problems with Bt cotton in Burkina Faso are therefore not related to the Bt trait or GM technology per se. Rather they are the consequence of what were arguably some poor choices of plant material during the breeding process. Such mistakes can be relatively easily rectified but this will take several years and a continued commitment by all parties to the project, which may not be forthcoming in the present case. The experience in Burkina Faso, points to the importance for African countries to build their own capacity and PPPs enabling them to develop biotechnology crops adopted to the needs of their local farmers and local markets. The Burkina Faso case

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notwithstanding, over the past two years there has been a distinct improvement in state engagement with biotech related PPPs in much of Africa. The major lessons from recent agbiotech PPP experiences are that success is dependent on a full commitment by host countries, appropriate regulatory systems, and the sustained participation of all partners, especially smallholders, over the entire duration of what can be complex and long term ventures. Prospects for sustained agricultural improvement in Africa, including but by no means limited to biotech-related crops, are now particularly bright, as outlined in recent articles in the Economist (25) and elsewhere (26, 27).

The potential impact of new genome editing biotechnologies

During the last few years, and especially in 2015, there has been a veritable revolution in genetic technologies with the development of genome editing methods such as CRISPR and TALENs (28-31). Genome editing technologies are already being used for the improvement of both livestock (33) and crops (3437). In terms of crop breeding, this means that it will soon be possible to progress from the random insertion of single or a small numbers of genes into a genome (as in traditional GM) to the highly precise insertion into a defined location of large numbers of genes, chromosome segments or pseudosegments encoding entire metabolic pathways into virtually any plant species (3). Another significant aspect of the new genome editing systems is that, in some cases, it may be virtually impossible to detect any resultant modifications in a genome. This is in contrast to conventional late-20th century GM methods where the presence of novel DNA can be readily detected (28, 33). Therefore some new genome edited plants may not carry any proof whether they were produced either via a GM-type technology or via one of several nonGM technologies that could have been used instead. This development has the potential to undermine the entire framework that is currently used for the regulation of GMOs because, for example, it would become impossible to distinguish between a new plant cultivar that has arisen via spontaneous mutation and a

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Figure 4. Professor Denis Murphy, University of South Wales, UK addressing the FAO Symposium on Agricultural Biotechnologies about some of the new developments in agbiotech including the use of genome editing technologies for crop and livestock improvement. Picture courtesy of FAO. non-GM plant produced via deliberate to advise it on the ever-expanding mutagenesis in the lab or a GM plant plant-breeding toolbox but the panel’s that has been deliberately modified by report, submitted in 2012, was never genome editing. published. It has been argued that these new There have been many scientific technologies could make some of publications that have highlighted the the current GM methods (and their need for a reconsideration of the EU regulation) obsolete and, as discussed regulatory environment for GM crops. below, there are already calls that, Nevertheless, even now, in 2016, there in some cases, organisms altered is little evidence of awareness amongst by genome editing should not be policymakers of how these new characterized as GMOs (33, 34). technologies and other advances in the Genome editing can considerably rapidly expanding field of biosciences widen the range of traits (especially are changing the conditions for smallholder relevant traits in hitherto breeding and crop production. orphan crops) to be altered much more There is an urgent need to revise, rapidly and cheaply than was hitherto adjust and modernize biosafety possible. The user friendliness and the regulations that were mostly designed comparatively low cost of the genome in the early 1990s (36-39) in order to editing technologies may also enable take account new technologies and low-income countries to leapfrog into new knowledge such as, but by no the world of precision breeding. means limited to, genome editing (29, This provides a golden opportunity for 40-44). the emergence of a new generation of In late 2015, an assessment about PPPs aimed specifically at improving whether plants created via the low profit smallholder agriculture as CRISPR/Cas9 system should be we face up to increasing food security classified as ‘GM’ was published by challenges across the world. the Swedish Board of Agriculture (SBA) (45). The conclusion was that while individual cases might differ, the A sluggish response to Arabidopsis plants examined in their study should not be regarded as GMOs agbiotech innovations in (see also Figure 5). It was stated that: “The SBA makes Europe the interpretation that those plants in Legislators in Europe have been slow the description mutated by CRISPR to respond to the developments in / Cas9 and which do not contain any genome editing technologies that have foreign DNA are exempted from the emerged over the past decade, but GM legislation.” (45) especially since 2014. Despite such clear and explicit As early as 2007 the European Commission appointed an expert panel evidence-based verdicts from this and

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Figure 5. Comparison between various methods to produce a new mutation in a plant and the potential regulatory implications. Diagram courtesy of Swedish Board of Agriculture. other expert studies, it is difficult to be model their own regulatory systems on optimistic that European regulations US systems, enabling technologies to will be modified in the near future to be disseminated to address agronomic recognise the new scientific landscape challenges and development arising from genome editing and opportunities. related technologies. Another way in which the context of In contrast, in the USA there are the GM debate has changed GMintensive consultations between related methods since the 1970s scientists, policymakers, and legislators is the growing evidence that gene on how to amend the current transfer between unrelated species in framework regulating the use advanced commonplace in the ‘natural’ world. agbiotech so that it ensures safety Prior to the 2000s, it was believed and sustainability but at the same time that the transfer of functional DNA continues to promote innovation and sequences between different species deployment of the fast advances in was limited to very simple organisms biosciences. such as bacteria. In contrast, it was Given the enormous potential of (and still is in many quarters) believed genome editing for developing country that the genomes of more complex crops (46), it seems more likely that organisms such as higher plants and many developing countries will tend to animals were relatively fixed within

individual species and that the insertion of exogenous DNA was therefore ‘unnatural’. This perspective has now entirely changed and there are many recently discovered examples of gene transfer between completely unrelated plants, animals and microbes leading to the creation of new genotypes and phenotypes that sometime have evolutionarily significant selective advantages (47, 48). In addition to naturally occurring DNA transfer between species, there are reports of soil bacteria acting as ‘natural’ genetic engineers by inserting novel genes into plants, including crops (49). The progeny of such plants will inherit the inserted bacterial genes and pass them on in turn to their descendants. This results in the non-human mediated creation of a completely new transgenic plant cultivar – in effect a ‘naturally occurring’ GMO. In the case reported by Kyndt et al. (49), a transgenic version of the sweet potato plant with four extra bacterial genes was found. Sweet potatoes have been grown by farmers as a food crop for millennia but, interestingly, wild relatives of sweet potato did not contain the bacterial genes. This means that humans have inadvertently selected a transgenic version of the sweet potato to grow as a crop in preference to nontransgenic versions. In the light of these discoveries, it is difficult to maintain the stance that GMOs themselves, and even the creation of GMOs (whether by humans or bacteria), are completely aberrant and fundamentally ‘unnatural’ instances of human interference in the wider biological world. In view of the growing scientific evidence about gene transfer in the ‘natural’ world and the emergence of radical, and sometimes undetectable, methods of genome editing it is arguably timely for a fundamental reappraisal of the nature of GM technologies to be undertaken. Such discussions are already underway in the Americas and elsewhere, but Europe continues to lag behind with a poor engagement and chronic lack of leadership in the international discourse on agbiotech, and especially its implementation and regulation (4). Unless this situation changes radically in the next few years, we may face a situation in which the rest of the world, including Africa, benefits from new breeding technologies and new genomic advances (some initiated by European researchers) while Europe itself becomes a stagnant backwater in

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terms of applied crop breeding and biotechnology. In essence it would mean that Europe might miss the opportunity to use this rapid and increasingly powerful toolbox of modern biosciences to develop productive, resource-efficient sustainable crop production systems for food, feed and agro-industrial products.

Conclusions and future prospects

Over recent decades there has been a somewhat polarised and largely sterile debate about several aspects of agbiotech, particularly relating to intensive farming practices and the use of GM technologies for crop cultivation. There has also been a great deal of pessimism about developing country agriculture, especially in Sub Saharan Africa. For a variety of reasons the region was unable to match the truly spectacular yield gains made in the rest of the developing world as part of the momentous Green Revolution in the 20th century. More recently, however, the have been signs that the rhetoric may be changing. ‘Conventional’ GM crops (i.e. those created using the original 20th century technologies of transgenesis via recombinant DNA methods) are now being increasingly deployed around the world, often as part of public sector-led PPPs aimed at smallholders. At present, the GM trait and seed market is still heavily concentrated among a few multinational actors and just four major global feed and commodity crops, maize, soybeans, rapeseed and cotton. However, we are now witnessing, not least in Africa and Asia, the development of a greater diversity of GM and non-GM crops, developed by a wider set of actors. These efforts will hopefully increase both the yield and quality of a wide variety of crops that would benefit a broad set of farmers and consumers and also the environment in the years to come (2527). This may be a new dawn for both industrialised and developing countries, making a wider use of the burgeoning toolkit now available for breeders and agronomists in addressing a set of environmental and development challenges. In particular, the use of genome editing and genomics technologies has the scope to greatly reduce the cost, and effectiveness and to lower the entrance barriers for the use of advanced biotechnologies.

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These should increase crop yield, quality and crop diversity. Moreover, they should lead to more resource efficient crop production systems tolerant to both increasing disease pressure and climatic stress. These new genetic technologies may eventually make much of the current ‘conventional’ GM-based crop improvement technologies and its risk assessment & regulation obsolete. There are already calls that organisms altered by genome editing should not be characterised as GMOs. Genome editing can considerably widen the range of traits (especially smallholder-relevant traits in hitherto orphan crops) that can be addressed through gene modification and these will be altered much more rapidly and cheaply than was hitherto possible. There is an urgent need to accelerate capacity building in all forms of agbiotech and related public outreach in all countries. This provides a golden opportunity for the emergence of a new generation of innovative PPPs and new agbiotech paradigms aimed specifically at improving smallholder agriculture as we face up to increasing food security challenges across the world. There is also, however, a common agreement that agbiotech is not a means in itself, but has to be combined with other disciplines and drivers such as agroecology, functional markets and value chains, to be fully effective.

References

1. Murphy DJ (2011) Current Status and Options for Crop Biotechnologies in Developing Countries, in Biotechnologies for Agricultural Development, pp 6-24, FAO, Rome, available online: http://www.fao. org/docrep/014/i2300e/i2300e.pdf http://www.fao. org/docrep/014/i2300e/i2300e00.htm 2. FAO, IFAD & WFP (2015) The State of Food Insecurity in the World 2015. Meeting the 2015 international hunger targets: taking stock of uneven progress. FAO, Rome. 3. Murphy DJ (2016) The potential of biosciences for agricultural improvement: looking forward to 2050, In Virgin I & Morris J, Eds, Creating Sustainable Bioeconomies, The Bioscience Revolution in Europe and Africa, Routledge, https:// www.routledge.com/products/9781138818538 4. Atanassov A et al (2010) 1 out of 27—European politicians score poorly in agbiotech, Nature Biotechnology 28, 551-552 5. Gridneff I (2012) GM for Uganda. Feeding the world or the greedy? The Global Mail, available online: http://tgm-archive.github.io/gmo-food/ ugandas-choice.html 6. Specter M (2014) Seeds of Doubt, The New Yorker, available online: http://www.newyorker.com/ magazine/2014/08/25/seeds-of-doubt 7. Annear CM (2004) “GM or Death”: Food and Choice in Zambia, Gastronomica 4:2, available online: http://www.gastronomica.org/gm-death-foodchoice-zambia/ 8. European Agencies Science Advisory Council (EASAC) (2013) Planting the future: opportunities and challenges for using crop genetic improvement technologies for sustainable agriculture EASAC policy report 21, available online: http://www.easac.

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eu/fileadmin/Reports/Planting_the_Future/EASAC_ Planting_the_Future_FULL_REPORT.pdf 9. UNFAO (2016) FAO Symposium on ‘The Role of Agricultural Biotechnologies in Sustainable Food Systems and Nutrition’, FAO, Rome, Italy, 15-17 February 2016, available online: http://www.fao.org/ about/meetings/agribiotechs-symposium/en/ 10. McKee D (2012) Bangladesh – road to selfsufficiency, available online: http://www.davidmckee. org/2012/11/17/bangladesh-road-to-self-sufficiency/ 11. FAO (2011) Bangladesh and FAO. Success stories and achievements, FAO, Rome, Italy, available online: http://www.fao.org/fileadmin/user_ upload/faobd/docs/Achievements/Bangladesh_ edoc_final_en.pdf 12. Mohindru SC (2013) Bangladesh Approves Cultivation of Genetically Modified Eggplant, Wall Street Journal, Nov 22, 2013, available online: http://www.wsj.com/articles/SB10001424052702303 653004579213572545045240 13. Entine J (2015) As success grows for Bangladesh’s Bt brinjal (eggplant), Mae-Wan Ho renews GMO disinformation campaign, Genetic Literacy Project, April 27, 2015, available online: https://www.geneticliteracyproject.org/2015/04/27/ as-success-grows-for-bangladeshs-bt-brinjaleggplant-mae-won-ho-renews-gmo-disinformationcampaign/ 14. James C (2014) Global Status of Commercialized Biotech/GM Crops: 2014. ISAAA Brief No. 49. ISAAA: Ithaca, NY, available online: http://www.isaaa.org/resources/publications/ briefs/49/ 15. FAO (2015) Fourth private sector partnerships dialogue: Inclusive finance and investment models in agriculture, FAO, Rome, Italy, available online: www.fao.org/3/a-az567e.pdf 16. Murphy DJ (2014) Modern plant breeding technologies and PPPs, In: Proceedings of Workshop on public-private partnerships in plant breeding, Lusser M, Ed, Joint Research Centre, Publications Office, European Union, Luxembourg, available online: http://publications.jrc.ec.europa. eu/repository/bitstream/111111111/31968/1/ipts%20 jrc%2088788%20%28online%29%20final.pdf 17. WWF (2014) The Growth of Soy: Impacts and Solutions. WWF International, Gland, Switzerland, available online: http://wwf.panda.org/what_we_do/ footprint/agriculture/soy/soyreport/ 18. Barona E (2010) The role of pasture and soybean in deforestation of the Brazilian Amazon, Environ. Res. Lett. 5 024002, available online: http://iopscience.iop.org/ article/10.1088/1748-9326/5/2/024002/pdf 19. Kameri-Mbote P et al (2001) Public / Private Partnerships for Biotechnology in Africa: The Future Agenda, Africa Centre for Technology Studies, Nairobi, available online: http://www.ielrc.org/ content/a0107.pdf 20. Bailey R et al (2014) On trial: agricultural biotechnology in Africa, Chatham House, available online: https://www.chathamhouse. org/sites/files/chathamhouse/field/field_ document/20140716BiotechAfrica.pdf?dm_ i=1TY5,2N30J,BHZLN4,9NERT,1 21. WEMA website (2016) http://wema.aatf-africa. org/about-wema-project 22. Schnurr M (2016) Bt Cotton in Burkina Faso, 2015 Conference: Can Genetically Modified Crops Help the Poor? available online: http:// gmosandpoverty.com/bt-cotton-in-burkina-faso/ 23. Dowd-Uribe B and Schnurr M (2016) Lessons to be learnt from Burkina Faso’s decision to drop GM cotton, The Conversation, Feb 2 2016, available online: http://theconversation.com/ lessons-to-be-learnt-from-burkina-fasos-decision-todrop-gm-cotton-53906 24. Burkina Faso plans to decrease planting area of Bt cotton, AgroNews, June 23, 2015, available online: http://news.agropages.com/News/ NewsDetail---15132.htm

25. Economist (2016) African agriculture, a green revolution, March 12, 23-25 26. Sanchez PA (2015) En route to plentiful food production in Africa, Nature Plants 1, 1-2 27. Cernansky, R. 2015. Super vegetables. Nature 522, pp.146-148 28. Ledford H (2015) CRISPR, the disruptor, Nature 522, 20-24 29. Ainsworth C. (2015). Agriculture: A new breed of edits, Nature 528, S14-15 30. Davis E. (2015). Genome Editing: Which Should I Choose, TALEN or CRISPR? Technical Note, GeneCopoeia Inc, available online: www. genecopoeia.com 31. Hsu PD, et al. (2014) Development and applications of CRISPR-Cas9 for genome engineering, Cell 157, 1262-1278 32. Petherick A et al (2015) Genome editing, Nature 528 S1-S48 33. Lunshof J (2015) Regulate gene editing in wild animals, Nature 521, 127 34. Mao Y, et al. (2013) Application of the CRISPRCas system for efficient genome engineering in plants, Molecular Plant 6, 2008-2011 35. Ricroch AE and Hénard-Damave MC (2015) Next biotech plants: new traits, crops, developers and technologies for addressing global challenges, Critical Reviews in Biotechnology doi:10.3109/0738 8551.2015.1004521 36. Zhang H et al (2014) The CRISPR/Cas9 system produces specific and homozygous targeted gene editing in rice in one generation, Plant Biotechnology Journal 12:797-807

37. Abbott, A. (2015). Europe’s genetically edited plants stuck in legal limbo. Scientists frustrated at delay in deciding if GM regulations apply to precision gene editing. Nature 528, 319-320 38. Anon (2015a) Seeds of change. The European Union faces a fresh battle over next-generation plant-breeding techniques, editorial, Nature 520, 131-132 39. Anon (2015b). Crop conundrum. The EU should decide definitively whether gene-edited plants are covered by GM laws. Nature 528, 307-308 40, ACRE (2012) ACRE advice: New techniques used in plant breeding, Advisory Committee on Releases to the Environment, UK, available online: https://www.gov.uk/government/uploads/ system/uploads/attachment_data/file/239542/newtechniques-used-in-plant-breeding.pdf 41. Ainsworth, C. (2015). Agriculture: A new breed of edits. Nature 528, S14-15 42. Wolt JD et al (2016) The Regulatory Status of Genome-edited Crops, Plant Biotechnology Journal 14, 510-518 43. Huang S et al (2016) A proposed regulatory framework for genome-edited crops, Nature Genetics 48, 109-111 44. Roberts AF, et al. (2015) Biosafety research for non-target organism risk assessment of RNAibased GE plants, Frontiers in Plant Science 6:958 45. Eklöf, S. (2015). CRISPR/Cas9 mutated Arabidopsis, Swedish Board of Agriculture, Jönköping, available online: http://www.umu.se/ digitalAssets/171/171717_backgroud-psbs.pdf http://www.upsc.se/documents/Information_on_

scientific

interpretation_on_CRISPR_Cas9_mutated_plants_ Final.pdf 46. Erbentraut, J. and Shapiro, L. (2015) The Genetic Revolution Could Curb World Hunger And Pesticide Use, HiffPost Science, 12 Dec 2015 47. Gao, C., et al. (2014). Horizontal gene transfer in plants, Functional and Integrative Genomics 14, 23-29 48. Soucy, S.M. et al. (2015). Horizontal gene transfer: building the web of life, Nature Reviews Genetics 16, 472-482 49. Kyndt, T, et al. (2015). The genome of cultivated sweet potato contains Agrobacterium T-DNAs with expressed genes: An example of a naturally transgenic food crop, Proceedings of the National Academy of Sciences 112, 5844-5849 50. Hopkins M (2015) DuPont, Caribou Biosciences Form Strategic Alliance, CropLife, October 8, 2015, available online: http://www.croplife.com/cropinputs/dupont-caribou-biosciences-form-strategicalliance/ 51. Ledford, H (2016) Alternative CRISPR system could improve genome editing, Smaller enzyme may make process simpler and more exact, Nature 526, doi:10.1038/nature.2016.19114 52. Shmakov S (2015) Discovery and Functional Characterization of Diverse Class 2 CRISPR-Cas Systems, Molecular Cell 60, 385-39 53. Burnstein D et al (2016) Major bacterial lineages are essentially devoid of CRISPR-Cas viral defence systems, Nature Communications 7:10613

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