Genetic engineering evokes a number of objections that are not directed at the negative effects the technique might have on the health and welfare of the modified animals. The concept of animal integrity is often invoked to articulate these kind of objections. Moreover, in reaction to the advent of genetic engineering, the concept has been extended from the level of the individual animal to the level of the genome and of the species. However, the concept of (...) animal integrity was not developed in the context of genetic engineering. Given this external origin, the aim of this paper is to critically examine the assumption that the concept of integrity, including its extensions to the level of the genome and the species, is suitable to articulate and justify moral objections more specifically directed at the genetic engineering of animals. (shrink)

There are many ways that biological theory can inform ethical discussions of genetic engineering and biomedical enhancement. In this essay, we highlight some of these potential contributions, and along the way provide a synthetic overview of the papers that comprise this special issue. We begin by comparing and contrasting genetic engineering with programs of selective breeding that led to the domestication of plants and animals, and we consider how genetic engineering differs from other contemporary (...) biotechnologies such as embryo selection. We go on to consider the implications of genetic engineering for human nature, human evolution, and persistence of the human species. Finally, we question whether genetic interventions warrant the extraordinary ethical scrutiny they are often given, and we show how the misleading “genetic blueprint” metaphor has imposed a faulty structure on the enhancement debate. We conclude by considering the nature of biological development and the sobering limits it places on what genetic engineering can reasonably hope to achieve. (shrink)

Genetic modification leads to several important moral issues. Up until now they have mainly been discussed from the viewpoint that only individual living beings, above all animals, are morally considerable. The standpoint that also collective entities such as species belong to the moral sphere have seldom been taken into account in a more thorough way, although it is advocated by several important environmental ethicists. The main purpose of this article is to analyze in more detail than often has been (...) done what the practical consequences of this ethical position would be for the use of genetic engineering on animals and plants. The practical consequences of the holistic standpoint (focused on collective entities) of Holmes Rolston, III, is compared with the practical consequences of the individualistic standpoints (focused on individual living beings) of Bernard E. Rollin and Philipp Balzer, Klaus Peter Rippe, and Peter Schaber, respectively. The article also discusses whether the claim that species are morally considerable is tenable as a foundation for policy decisions on genetic engineering. (shrink)

The Swiss expert report suggests thatthe inherent dignity of a living being be identifiedwith its inherent value. But the phrase ``inherentvalue of a living being'' seems to connote two conceptsof inherent value. One has a morally obligatingcharacter but is counterintuitive because of itsegalitarianism. The other is one of non-moral value.It is more compatible with considered intuitions butinsufficient for substantiating the expert report'sclaim that human beings have moral duties towardsanimals and plants. The paper discusses theseconcepts. Consideration is then given to the (...) problemof how discursive support can be generated for theexpert report's claim that human beings have the moralduty to abstain from impairing those functions andabilities of a nonuman being that members of itsspecies as a rule can practice. (shrink)

Imagine a world in which as part of their basic substances tomatoes contain fish and tobacco, potatoes contain chicken, moths and other insects, and corn contains fireflies. Is this science-fiction? No, these plant-animal hybrids already exist today and may soon be on your supermarket shelves without any special labeling to warn you. Furthermore, in a few years the types of these genetically engineered "vegetables" are sure to increase and may very possibly also include human genes. If you are a (...) vegetarian, do you want to be in the position of inadvertently eating vegetables that are part meat? Even if you are not a vegetarian, are you ready to become a cannibal and eat foods that are part human being? (shrink)

The current debate about labeling genetically engineered (GE) food focuses on food derived from GE crops, neglecting food derived from GE animals. This is not surprising, as GE animal products have not yet reached the market. Participants in the debate may also be assuming that conclusions about GE crops automatically extend to GE animals. But there are two GE animals - the Enviropig and the AquAdvantage Bred salmon - that are approaching the market, animals raise more ethical issues than plants, (...) and U.S. regulations treat animal products differently from crops. This paper therefore examines the specific question of whether there should be mandatory labeling on all food products derived from GE animals. We examine the likely regulatory pathways, salient differences between GE animals and GE crops, and relevant social science research on consumers’ attitudes. We argue that on any of the likely pathways, the relevant agency has a democratic obligation to require labeling for all GE animal food products. (shrink)

Traditionally, plant viruses are viewed as harmful, undesirable pathogens. However, their genomes can provide several useful ‘designer functions’ or ‘sequence modules’ with which to tailor future gene vectors for plant or general biotechnology.The majority (77 %) of known plant viruses have single‐stranded RNA of the messenger (protein coding) sense as their genetic material. Over the past 4 years, improved in vitro transcription systems and the construction of partial of fulllength DNA copies of several plant RNA (...) viruses have enhanced our ability to manipulate and study their genomes, particularly in the context of their pathogenic interactions with host plants.Recently, two forms of genetically engineered protection against plant virus infections have been reported. In both, a virus‐related ‘interfering’ molecule was stably introduced into plants via the DNA‐transfer mechanism of Agro‐bacterium tumefaciens. To date, the choice of ‘interfering’ molecule has been guided by empirical field‐observations and each is effective against only a narrow range of closely‐related viruses. As yet, we do not fully understand the molecular mechanism(s) responsible for the observed protection.The ability to manipulate the plant–pathogen relationship is a powerful tool to increase our knowledge and improve future strategies for uncoventional cropprotection by genetic engineering techniques. (shrink)

There are many risks involved in genetic engineering. The release of genetically altered organisms in the environment can increase human suffering, decrease animal welfare, and lead to ecological disasters. The containment of biotechnological material in laboratories and industrial plants contributes to the risk of accidental release, especially if the handling and storage are inadequate. The purely political dangers include intensified economic inequality, the possibility of large-scale eugenic programs, and totalitarian control over human lives. How should the acceptability of (...) these risks be determined? We argue that the assessment should be left to those who can be harmed by the decisions in question. Economic risks are acceptable, if they are condoned by the corporations and governments who take them. The risks imposed on laboratory personnel by the containment of dangerous materials ought to be evaluated by the laboratory personnel themselves. All other risks are more or less universal, and should therefore be assessed as democratically as possible. If risk-taking is based on the choices of those who can be harmed by the consequences, then, even if the undesired outcome is realized, the risk is acceptable, because it is embedded in their own system of ethical and epistemic values. (shrink)

The ability of medical science to clone and perhaps even predetermine characteristics of certain species conflicts dramatically with many claims of the religious establishment. Opening with a description of various developments in plant, animal, and human genetics, Made in Whose Image? highlights the progress genetic research has achieved, its future promise, and its social impact. The developments are analyzed from the perspective of Christian ethics, as expounded by Roman Catholic and Protestant theorists, to give an overview of crucial (...) ethical issues. In reviewing the advances of genetic research, noted religion and ethics professor Thomas A. Shannon covers general ethical themes, such as the value of life, materialism, freedom, individuality, the concept of nature, and health and disease. In addition, he discusses problems in genetic engineering and misconceptions of the church. Shannon explores prenatal diagnosis, gene therapy, genes and behavior, freedom and responsibility, and the Human Genome Project. The book concludes with a powerful and groundbreaking methodological discussion of how to approach ethical problems in genetic engineering. (shrink)

From the very first milk you suckle, your food is genetically engineered. The natural world is completely made over, invaded and distorted beyond recognition by genetically engineered trees, plants, animals, insects, bacteria, and viruses, both planned and run amok. Illnesses are very different too. Most of the old ones are gone or mutated into new forms, yet most people are suffering from genetically engineered pathogens, either used in biowarfare, or mistakenly released into the environment, or recombined in toxic form from (...) originally harmless but rapidly mutating engineered organisms. Genetic engineering is so commonplace, you start your own simple experiments with it in elementary school. (shrink)

In this paper I critique two popular, non-scientific attitudes toward genetically engineered foods. In doing so, I will be employing the concepts of ambiguity, purity/impurity, control/resistance, and unity/diversity as developed by Latina feminist metaphysicians. I begin by casting a critical eye toward a specific anti-biotech account of transgenic food crops, an account that I will argue relies on an anti-feminist metaphysics. I then cast that same critical eye toward a specific pro-biotech account, arguing that it also relies on such an (...) anti-feminist metaphysics. I will argue further that this metaphysics yields a less accurate account of genetics. I end by arguing that if we adopt a Latina feminist metaphysics we can more accurately understand plants, genetics, and genetic engineering. (shrink)

Recent experiments have been used to “edit” genomes of various plant, animal and other species, including humans, with unprecedented precision. Furthermore, editing the Cas9 endonuclease gene with a gene encoding the desired guide RNA into an organism, adjacent to an altered gene, could create a “gene drive” that could spread a trait through an entire population of organisms. These experiments represent advances along a spectrum of technological abilities that genetic engineers have been working on since the advent of (...) recombinant DNA techniques. The scientific and bioethics communities have built substantial literatures about the ethical and policy implications of genetic engineering, especially in the age of bioterrorism. However, recent CRISPr/Cas experiments have triggered a rehashing of previous policy discussions, suggesting that the scientific community requires guidance on how to think about social responsibility. We propose a framework to enable analysis of social responsibility, using two example.. (shrink)

Biotechnology applied to traditional foodanimals raises ethical issues in three distinctcategories. First are a series of issues that arise inthe transformation of pigs, sheep, cattle and otherdomesticated farm animals for purposes that deviatesubstantially from food production, including forxenotransplantation or production of pharmaceuticals.Ethical analysis of these issues must draw upon theresources of medical ethics; categorizing them asagricultural biotechnologies is misleading. The secondseries of issues relate to animal welfare. Althoughone can stipulate a number of different philosophicalfoundations for the ethical assessment of welfare,most (...) either converge on Bernard Rollins principle ofwelfare conservation (Rollin, 1995), or devolve intodebates over the ethical significance of animaltelos or species integrity. The principle of welfareconservation prohibits disfunctional geneticengineering of food animals, but would permit alteringanimals biological functions, especially when (as inmaking animals less susceptable to pain or suffering)do so improves an individual animals well being.Objections to precisely this last form of geneticengineering stress telos or species integrity asconstraints on modification of animals, and thisrepresents the third class of ethical issues. Most whohave formulated such arguments have failed to developcoherent positions, but the notion of species being,derived from the 19th century German tradition,presents a promising way to analyze the basis forresisting the transformation of animal natures. (shrink)

What makes humans different from other animals, what humans are entitled to do to other species, whether time travel is possible, what limits should be placed on science and technology, the morality and practicality of genetic engineering—these are just some of the philosophical problems raised by Planet of the Apes. Planet of the Apes and Philosophy looks at all the deeper issues involved in the Planet of the Apes stories. It covers the entire franchise, from Pierre Boulle’s 1963 (...) novel Monkey Planet to the successful 2012 reboot Rise of the Planet of the Apes. The chapters reflect diverse points of view, philosophical, religious, and scientific. The ethical relations of humans with animals are explored in several chapters, with entertaining and incisive observations on animal intelligence, animal rights, and human-animal interaction. Genetic engineering is changing humans, animals, and plants, raising new questions about the morality of such interventions. The scientific recognition that humans and chimps share 99 percent of their genes makes a future in which non-human animals acquire greater importance a distinct possibility. Planet of the Apes is the most resonant of all scientific apocalypse myths. (shrink)

The repertory grid method was used to determine what terminology respondents use to distinguish between different applications of genetic engineering drawn from food- related, agricultural, and medical applications. Respondents were asked to react to fifteen applications phrased in general terms, and results compared with a second study where fifteen more specific applications were used as stimuli. Both sets of data were submitted to generalized Procrustes analysis. Applications associated with animals or human genetic material were described as causing (...) ethical concern, being unnatural, harmful, and dangerous. Those involving plants or microorganisms were described as beneficial, progressive, and necessary. The results were validated in survey research, which indicated that general applications ofgenetic engineering were perceived as either positive or negative, whereas specific applications were more highly differentiated in perceptual terms. The results imply that the public debate about genetic engineering must take due account of the complexity of public concerns. (shrink)

Forty years’ experience as a bacterial geneticist has taught me that bacteria possess many cognitive, computational and evolutionary capabilities unimaginable in the first six decades of the twentieth century. Analysis of cellular processes such as metabolism, regulation of protein synthesis, and DNA repair established that bacteria continually monitor their external and internal environments and compute functional outputs based on information provided by their sensory apparatus. Studies of genetic recombination, lysogeny, antibiotic resistance and my own work on transposable elements revealed (...) multiple widespread bacterial systems for mobilizing and engineering DNA molecules. Examination of colony development and organization led me to appreciate how extensive multicellular collaboration is among the majority of bacterial species. Contemporary research in many laboratories on cell–cell signaling, symbiosis and pathogenesis show that bacteria utilise sophisticated mechanisms for intercellular communication and even have the ability to commandeer the basic cell biology of ‘higher’ plants and animals to meet their own needs. This remarkable series of observations requires us to revise basic ideas about biological information processing and recognise that even the smallest cells are sentient beings. Previous article in issue. (shrink)

In lieu of an abstract, here is a brief excerpt of the content:FDA Releases Draft Guidance on Regulation of Genetically Engineered AnimalsJohn P. Gluck (bio) and Mark T. Holdsworth (bio)On 18 September 2008, the U.S. Food and Drug Administration (FDA) issued a draft set of guidelines for those involved in developing genetically engineered animals with heritable recombinant DNA (rDNA) constructs and is requesting comment from industry and the public about their content. The document does not impose new regulations but details (...) how existing laws and regulations apply to genetically engineered (GE) animals and offers advice to developers on how to negotiate the laws in the most efficient and productive manner. The draft guidance document is not legally enforceable at this juncture, but the guidelines are recommendations reflecting the FDA's "current thinking on a topic."The modification of GE animals being developed for commercialization, which are the focus of the document, fall into six categories: modifications intended to (1) enhance food quality—e.g., faster growing fish and meats with better nutritional profiles; (2) improve animal health via increased resistance to disease—e.g., mastitis in dairy cattle and Bovine Spongiform Encephalopathy (BSE); (3) create so-called "biopharm" animals capable of producing therapeutic products such as insulin, clotting factors, and tissues for human transplantation; (4) reduce the barriers to human animal interaction—e.g., hypoallergenic pets; (5) develop valid animal models of human disease—e.g., Parkinson's disease, Lesh-Nyhan's syndrome, and cancer; and (6) improve production of industrial or consumer products such as fiber. The timing of the guidelines coincides with the FDA's belief in an expected boon in the number of GE animals approaching the stage of commercialization.The FDA's involvement in the approval process emerges from the new animal drug provisions of the Federal Food Drug and Cosmetic Act and the definition of what constitutes a drug. The Act defines a new animal drug as "an article (other than food) intended to affect the structure or any function of the body of... animals." A rDNA construct intended to affect the structure or function of an animal meets the definition of a new animal drug, regardless of whether the resulting GE animals are intended for human food or the production of pharmaceuticals or any other substances. [End Page 393]Before proceeding to a review of the draft guidelines, it is important briefly to set the controversies around GE animals in historical and ethical context.The Ethical DebateFrom its inception, the intentional genetic modification or genetic engineering of molecules, plants, and animals by the techniques of gene splicing has consistently elicited strong responses from both the scientific community and the public. There are some data to suggest that although the concerns of scientists fall primarily into the category of possible biohazards, those of the public also reflect great concern about the intrinsic moral issues, such as whether there is something fundamentally wrong with this line of work, making it a form of forbidden knowledge (see, e.g., Gaskell 1997). When news of Paul Berg's attempts in 1970 to graft the primate tumor virus (SV 40) onto the intestinal tract bacteria Escherichia coli for the purpose of studying how normal cells may be transformed into cancerous cells was shared with colleagues, he was strongly encouraged to reflect on the potential public health risks if somehow the altered bacteria broke containment and entered the environment. Thanks to Berg's leadership, these concerns soon resulted in conferences held in Asilomar, California, and New Hampton, New Hampshire, where the ethical responsibilities of microbiologists involved in this research were discussed. These initial discussions resulted in what has come to be known as "The Moratorium Letter" (Shattuck 1996) published in the journal Science in 1974. This letter, signed by 11 leaders in the field, actually recommended restrictions on several types of experiments that were considered to be particularly risky and stated "that adherence to our major recommendations will entail postponement or possibly abandonment of certain types of scientifically worthwhile experiments" (Berg 1974). An international conference on the issues came to similar conclusions about the need for a research moratorium for the sake of public safety. Recommendations arising from conference participants led to the formation of the National Institutes... (shrink)

Forty years’ experience as a bacterial geneticist has taught me that bacteria possess many cognitive, computational and evolutionary capabilities unimaginable in the first six decades of the twentieth century. Analysis of cellular processes such as metabolism, regulation of protein synthesis, and DNA repair established that bacteria continually monitor their external and internal environments and compute functional outputs based on information provided by their sensory apparatus. Studies of genetic recombination, lysogeny, antibiotic resistance and my own work on transposable elements revealed (...) multiple widespread bacterial systems for mobilizing and engineering DNA molecules. Examination of colony development and organization led me to appreciate how extensive multicellular collaboration is among the majority of bacterial species. Contemporary research in many laboratories on cell–cell signaling, symbiosis and pathogenesis show that bacteria utilise sophisticated mechanisms for intercellular communication and even have the ability to commandeer the basic cell biology of ‘higher’ plants and animals to meet their own needs. This remarkable series of observations requires us to revise basic ideas about biological information processing and recognise that even the smallest cells are sentient beings. (shrink)

New Breeding Techniques such as CRISPR-Cas9 are revolutionizing plant breeding and food production. Experts believe that the social debate about these technologies could be similar to those on green genetic engineering: emotional and highly controversial. Future debate about Genome Editing could benefit from a better understanding of the GMO (genetically modified organism) controversy. Against this background, this paper (a) presents results of a content analysis of position papers criticizing green genetic engineering in Germany. In particular, (...) (b) it focuses on the controversy as a place where normative concepts of nature are debated and become visible. Hence, the study complements existing interpretations by showing that the emerging concepts are more diverse than the familiar reductionist breakdown of the debate into anthropocentric vs. non-anthropocentric conceptions suggests. (shrink)

The main purpose of The NorwegianGene Technology Act (1993) is to enforcecontainment of genetically modified organisms(GMOs) and control of GMO releases.Furthermore, the Act intends to ensure that``production and use of GMOs should take placein an ethically and socially justifiable way,in accordance with the principle of sustainabledevelopment and without detrimental effects tohealth and the environment.'' Hence it isobvious that, for the Norwegian authorities,sustainable development is a normativeguideline when evaluating acceptableconsequences of GMO use and production. Inaccordance with this, we have investigated theextent (...) to which the sustainability criteriawere decisive for the destiny of one approvedand one declined application of geneticallymodified plant release. The presentunderstanding of the ecological,socio-economical, and cultural consequences ofGMO use and release is fragmentary anduncertain. We consider the PrecautionaryPrinciple and the notion of equitabledistribution as key issues within thesustainable development framework, henceconstituting important foundations for ouranalyses. The Act is legitimizingsustainability criteria, but does not seem tosecure their conversion into concrete action.We envisage a more conscious implementation ofthe Norwegian Gene Technology Act.Sustainability concerns ecological, economical,and social values, and these can only beensured through long-term thinking, initiationof independent risk-associated research, andbroad involvement of all stakeholders in theevaluation of GMO issues and concerns. (shrink)

Social policies are used to regulate how members of a society interact and share resources. If we expand our sense of community to include the ecosystem of which we are a part, we begin to develop an ethical obligation to this broader community. This ethic recognizes that the environment has intrinsic value, and each of us, as members of society, are ethically bound to preserve its sustainability. In assessing the environmental risks of new agricultural methods and technologies, society should not (...) freely trade economic gains for ecological damage, but rather seek practices that are compatible with ecosystem health. This approach is used to evaluate the environmental risks associated with genetically engineered insect-resistant trees. The use of insect-resistant trees is a biologically based pest control strategy that has several advantages over pesticide use. However, the use of genetically engineered trees presents particular ecological concerns because the trees are long lived and often are not highly domesticated. The main environmental concerns reviewed include: (1) adaptation of pests to the trees, leading to a non-sustainable agricultural practice, (2) transgenic trees producing environmental toxins, (3) insect resistance enhancing the invasiveness of the tree, causing it to become weedy or invade wild habitats, and (4) transfer of the transgene to wild or feral relatives of the tree, possibly increasing the invasiveness of weeds or wild plants. Some methods are available to offset these risks; however, the environmental risks associated with this technology have been poorly researched and need to be more clearly identified so that when we evaluate the risks, it is based on the best information obtainable. To fulfil an ethical obligation to the environment, public policies and government regulations are needed to preserve the sustainability of both the environment and the future of our production systems. A better understanding of both the ecological issues and of genetic engineering in general are needed on the part of citizens and policy makers alike to ensure that sound environmental decisions are made. Otherwise, the environmental benefits of this technology, mainly decreasing the use of more toxic pesticides in tree crops and forests, will either be lost or traded for other environmental hazards. (shrink)

The development of genetic engineering and its plausible consequences raises a level of controversy that can be identified at the level of public rather than scientific debate. Opposition to genetic engineering may manifest itself in rejection of the technology overall, or rejection of specific aspects of the technology, where public attitudes may be defined by a complex set of perceptions incorporating risk, benefit, control, and ethical concerns.One hundred and seventy six members of the public responded to (...) questionnaires about genetic engineering that were framed in terms of either food production or medical application. The first section assessed perceived risks, benefits, and control of genetic engineering where the targets of the potential application and the location of control were varied. The second section assessed the relationship between objections to application of the technology to different types of organisms (plants, microorganisms, animals, or human genetic material). Questions were directed at either perceived risk or ethical objections. The applications of genetic engineering were seen as riskier and less beneficial when applied to food production than medicine, although perceived control was independent of application. Optimistic bias was observed. Ethical and risk related objections were greater for applications to food than to medicine, and again dependent on the type of organism manipulated. The transfer of genetic material between “dissimilar” types of organism (for example, between plants and animals) were not associated with greater risk or ethical concern than transfers between “similar” types of organism (for example, between animals and animals). The public requirement for legislative control was also dissociated into risk or ethical objections to the technology, and found to be greater for risk-related concerns, although ethical considerations were also important. (shrink)

This survey was conducted in 2017 to investigate factors influencing social risk perception of biotechnologists and plant breeders in training toward GM food based on a conceptual model. A random sample of 210 biotechnologists and plant breeders in training was studied. Confirmatory factor analysis and the reliability tests have been used to verify the uni-dimensionality of the measurement scale, SEM also was carried out to determine the most parsimonious models with the best fit for social risk perception of (...) GM foods and path analysis was conducted to understand the exogenous variables introduced in the research model. The findings revealed that the engineers in training had moderate social risk perception regarding GM foods. Moreover, the results of structural equation modeling showed the capability of the model in predicting the social risk perceptions of engineers in training. The psychological attributes of risks, social benefit perception, attitude toward using technology, level of religiosity, and moral and ethical beliefs emerged as the most powerful predictors of the social risk perception. The social benefit perception and attitude toward using technology also mediated the effects of psychological attributes of risks, level of religiosity, and moral and ethical beliefs. The social benefit perception also had an indirect influence on the engineers in training’s social risk perception of GM foods. Finally, we recommend the application of the model developed by this study for better understanding of social risk perception of stakeholders to have a more informed view of the development and promotion of GM foods. (shrink)

Abstract.Since the gene splicing debates of the 1980s, the public has been exposed to an ongoing sequence of genetic and reproductive technologies. Many issue areas have outcomes that lose track of people's inner values or engender opposing religious viewpoints defying final resolution. This essay relocates the discussion of what is an acceptable application from the individual to the societal level, examining technologies that stand to address large numbers of people and thus call for policy resolution, rather than individual fiat, (...) in their application. A major source of guidance is the “Genetic Frontiers” series of professional dialogues and conferences held by the National Conference for Community and Justice from 2002 to 2004. Genetic testing, human gene therapy, genetic engineering of plants and animals, and stem cell technology are examined. While differences in perspective on the beginning of life persist, a stepwise approach to the examination of genetic testing reveals areas of general agreement. Stewardship of life, human co‐creativity with the divine, and social justice help define the bounds of application of genetic engineering and therapy; compassionate care plays a major role in establishing stem cell policy. Active, sustained dialogue is a useful resource for enabling sharing of religious values and crystallization of policies. (shrink)

In recent years, humans’ ability to selectively modify genes has increased dramatically as a result of the development of new, more efficient, and easier genetic modification technology. In this paper, we argue in favor of using this technology to improve the welfare of agricultural animals. We first argue that using animals genetically modified for improved welfare is preferable to the current status quo. Nevertheless, the strongest argument against pursuing gene editing for welfare is that there are alternative approaches to (...) addressing some of the challenges of modern agriculture that may offer ethical advantages over genetic modification; namely, a dramatic shift towards plant-based diets or the development of in vitro meat. Nevertheless, we provide reasons for thinking that despite these possible comparative disadvantages there are important reasons for continuing the pursuit of welfare improvements via genetic modification. (shrink)

In discussions on genetic engineering and plant breeding, the intrinsic value of plants and crops is used as an argument against this technology. This paper focuses on the new field of plant genomics, which, according to some, is almost the same as genetic engineering. This raises the question whether the intrinsic value of plants could also be used as an argument against plant genomics. We will discuss three reasons why plant genomics could (...) violate the intrinsic value of plants: 1. genomics is part of biotechnology; 2. genomics equals genetic engineering; 3. plant genomics may enhance trends that lead to the instrumentalization of plants. We will conclude that in the biotic view the intrinsic value of plants is violated by plant genomics only in case of 'the genomics equals genetic engineering scenario'. (shrink)

1. Introduction -- 2. Philosophy of genetic technology and its relation to ethical theories -- 3. Ethics of genetic technology in plants and animals -- 4. Ethics of genetic technology in humans -- 5. Conclusion.

Focused on the impact of stringent intellectual property mechanisms over the uses of plant agricultural biodiversity in crop improvement, the article delves into a systematic analysis of the relationship between institutional paradigms and their technological contexts of application, identified as mass selection, controlled hybridisation, molecular breeding tools and transgenics. While the strong property paradigm has proven effective in the context of major leaps forward in genetic engineering, it faces a systematic breakdown when extended to mass selection, where (...) innovation often displays a collective nature. However, it also creates partial blockages in those innovation schemes rested between on-farm observation and genetic modification, i.e. conventional plant breeding and upstream molecular biology research tools. Neither overly strong intellectual property rights, nor the absence of well delineated protection have proven an optimal fit for these two intermediary socio-technological systems of cumulative incremental innovation. To address these challenges, the authors look at appropriate institutional alternatives which can create effective incentives for in situ agrobiodiversity conservation and the equitable distribution of technologies in plant improvement, using the flexibilities of the TRIPS Agreement, the liability rules set forth in patents or plant variety rights themselves, and other ad hoc reward regimes. (shrink)

This article is concerned with a discussion of the plausibility of the claim that GM technology has the potential to provide the hungry with sufficient food for subsistence. Following a brief outline of the potential applications of GM in this context, a history of the green revolution and its impact will be discussed in relation to the current developing world agriculture situation. Following a contemporary analysis of malnutrition, the claim that GM technology has the potential to provide the hungry with (...) sufficient nourishment will be discussed within the domain of moral philosophy to determine whether there exists a moral obligation to pursue this end if and only if the technology proves to be relatively safe and effective. By using Peter Singer’s duty of moral rescue, I argue that we have a moral duty to assist the third world through the distribution of such GM plants. I conclude the paper by demonstrating that my argument can be supported by applying a version of the Precautionary Principle on the grounds that doing nothing might be worse for the current situation. (shrink)

Clustered, regularly interspaced, short palindromic repeat (CRISPR)/CRISPR‐associated protein (CRISPR/Cas) system has revolutionized genetic research in the life sciences. Four classes of CRISPR/Cas‐derived genome editing agents, such as nuclease, base editor, recombinase, and prime editor have been introduced for engineering the genomes of diverse organisms. The recently introduced prime editing system offers precise editing without many off‐target effects than traditional CRISPR‐based systems. Many researchers have successfully applied this gene‐editing toolbox in diverse systems for various genome‐editing applications. This review presents (...) the mechanism of prime editing and summarizes the details of the prime editing system applied in plants and mammalian cells for precise genome editing. We also discuss the advantages, limitations, and potential future applications of prime editing in these systems. This review enables the researcher to gain knowledge on prime editing tools and their potential applications in plants and mammalian cells. (shrink)

This review provides a current perspective on the insertion of genes into plants. Some of the knowledge on the structure and control of plant genes gained recently from genetic engineering approaches is described, together with developments that can be expected to emerge from further exploitation of gene transfer techniques.

Genetic engineering evokes a number of objections that are not directed at the negative effects the technique might have on the health and welfare of the modified animals. The concept of animal integrity is often invoked to articulate these kind of objections. Moreover, in reaction to the advent of genetic engineering, the concept has been extended from the level of the individual animal to the level of the genome and of the species. However, the concept of (...) animal integrity was not developed in the context of genetic engineering. Given this external origin, the aim of this paper is to critically examine the assumption that the concept of integrity, including its extensions to the level of the genome and the species, is suitable to articulate and justify moral objections more specifically directed at the genetic engineering of animals. (shrink)

The “Model for Reaching Ethical Judgments in the context of Modern Technologies — the Case of Genetic Technology”, which is presented here, has arisen from the project “Ethical Criteria bearing upon Decisions taken in the field of Biotechnology”. This project has been pursued since 1991 in the Zentrum für interdisziplinäre Technikforschung (ZIT) of the Technical University of Darmstadt, with the purpose of examining decision-making in selected activities involving the production of transgenic plants that have a useful application. The model (...) is the basis of an outline for interviews to investigate how far decisions concerning the development of such plants with genetic techniques take ethical criteria into account. It was necessary to design this new model because other models for reaching judgments of this kind were not conceptually suited for concrete application. This model represents a problem related approach and combines methodological with substantive typology. In this it differs from comparable models for reaching ethical judgments. (shrink)

Genetically engineered (GE) insects, such as the GE OX513A Aedes aegypti mosquitoes, have been designed to suppress their wild-type populations so as to reduce the transmission of vector-borne diseases in humans. Apart from the ecological and epidemiological uncertainties associated with this approach, such biotechnological approaches may be used by individual governments or the global community of nations to avoid addressing the underlying structural, systemic causes of those infections... We discuss here key ethical questions raised by the use of GE mosquitoes, (...) with the aim of fostering discussion between the public, researchers, policy makers, healthcare organizations, and regulatory agencies at the local, national, and international levels. We affect that goal by outlining a procedural approach to decision-making about the use of the “biotechnology” that goes beyond “community engagement.” The protocol we advocate for entails informed deliberations and decision-making at the community level. It is designed to ensure that the voices of the marginalized and vulnerable groups that would be disproportionately affected by the decision are heard during the community-wide discussions. Moreover, we make the case that the values embedded in the risk assessment should be identified so that the community can make an informed decision about the use of GE insects. In addition, we advocate for the involvement of a variety of actors whose responsibility would be to ensure that the community has the opportunity to make an informed decision based on deliberations about the use of the “biotechnology.”. (shrink)

Genetic engineering technologies are a subclass of the biotechnology family, and are concerned with the use of laboratory-based technologies to intervene with a given organism at the genetic level, i.e., the level of its DNA. This class of technologies could feasibly be used to treat diseases and disabilities, create disease-resistant crops, or even be used to enhance humans to make them more resistant to certain environmental conditions. However, both therapeutic and enhancement applications of genetic engineering (...) raise serious ethical concerns. This paper examines various objections to genetic engineering (as applied to humans) which have been raised in the literature, and presents a new way to frame these issues, and to look for solutions. Specifically, this paper frames genetic engineering technologies within the ‘design turn in applied ethics’ lens and thus situates these technologies as covarying with societal forces. The value sensitive design (VSD) approach to technology design is then appropriated as the conceptual framework in which genetic engineering technologies can be considered so that they can be designed for important human values. By doing so, this paper brings further nuance to the scholarship on genetic engineering technologies by discussing the sociotechnicity of genetic engineering systems rather than framing them as value-neutral tools that either support or constrain values based on how they are used. (shrink)

This chapter contains sections titled: The Various Uses of Genetic Engineering The Disability Rights Challenge to the Prevention of Disabilities The Goal of a World without Disabilities Use of Genetic Engineering to Enhance Normal Function Environmental versus Genetic Changes When are Enhancements Benefits? The Magnitude of Enhancement The Means Used for Enhancement Who is Using Genetic Engineering? Impact of Genetic Engineering on Fairness and Inequality Acknowledgments.

Genetically engineered animals that are meant for release in the wild could significantly impact ecosystems given the interwoven or entangled existence of species. Therefore, among other things, it is all too important that regulatory agencies conduct entity appropriate, rigorous risk assessments that can be used for informed decision-making at the local, national and global levels about the release of those animals in the wild. In the United States, certain GE animals that are intended for release in the wild may be (...) regulated as new animal drugs by the Food and Drug Administration. This paper argues that the decision to treat them as new animal drugs is attributable to the influence of neoliberalism on the US biotechnology regulatory policy framework. The case is made that there should be public democratic deliberations and decision-making about the values and concerns that should guide the nation’s biotechnology regulatory policy paradigm, including the risk assessment process for GE animals meant for release in the wild. -/- . (shrink)

Genetic engineering of life forms could well have a profound effect upon our sense of the sacred. Integrating the experience of the sacred as George Bataille does, we can characterize it as a phenomenological encounter with prelinguistic, noncategoreal experience. This view of the sacred is similar to Friedrich Nietzsche's Dionysian experience or Rudolf Otto's mysterium tremendum and diminishes one's sense of self. It seems similar to the eighteenth‐century aesthetic categorization of “the sublime.” Despite the dominant rational approach to (...) religiosity in the United States, intimations of this experience persist in popular culture. What possible relationship does genetic engineering have to this allegedly inevitable and profound experience? If certain modifications of life occur, they are likely to create such an experience of the sacred in us. In principle, we can now resurrect the mammoth or even create beings designed to directly potentiate our experience of the numinous such as satyrs or centaurs. The creation of such beings could become an art form associated with awaking the sacred, in turn appropriated by religion, as art has always been. Such experimentation, though morally questionable, is probably inevitable. (shrink)

This paper describes some likely semiotic consequences of genetic engineering on what Gregory Bateson has called “the mental ecology” of future humans, consequences that are less often raised in discussions surrounding the safety of GMOs. The effects are as follows: an increased 1) habituation to the presence of GMOs in the environment, 2) normalization of empirically false assumptions grounding genetic reductionism, 3) acceptance that humans are capable and entitled to decide what constitutes an evolutionary improvement for a (...) species, 4) perception that the main source of creativity and problem solving in the biosphere is anthropogenic. Though there are some tensions between them, these effects tend to produce self-validating webs of ideas, actions, and environments, which may reinforce destructive habits of thought. Humans are unlikely to safely develop genetic technologies without confronting these escalating processes directly. Intervening in this mental ecology presents distinct challenges for educators, as will be discussed. (shrink)

Genetic engineering often generates fear of out of control scientists creating Frankenstein creatures that will terrorize the general populace, especially in the cases of human-animal chimeras. While sometimes an accurate characterization of some researchers, this belief is often the result of repugnance for new technology rather than being rationally justified. To facilitate thoughtful discussion the moral issues raised by human-animal chimeras, ethicists and other stakeholders must develop a rational ethical framework before raw emotion has a chance of becoming (...) the dominating justification for public opinion and policy. Derek Parfit’s work on lives worth living for human beings can provide valuable insight into the morality of creating chimeras. As long as their lives are overall good, then bringing them into existence does not harm them even if they are used for medical research or procedures, or they are created to carry on the homo sapiens’ “family” line. (shrink)

The struggle over genetically-engineered (GE) maize in Mexico reveals a deep conflict over the criteria used in the governance of agri-food systems. Policy debate on the topic of GE maize has become “scientized,” granting experts a high level of political authority, and narrowing the regulatory domain to matters that can be adjudicated on the basis of scientific information or “managed” by environmental experts. While scientization would seem to narrow opportunities for public participation, this study finds that Mexican activists acting “in (...) defense of maize” engage science in multiple ways, using and producing scientific knowledge as well as treating scientific discussions as a stage for launching complex social critiques. Drawing from research in science and technology studies, this article assesses the impacts and pitfalls of three tactics used by maize activists that respond to the scientization of biotechnology politics: (1) using scientific information as a resource; (2) participating in scientific research; and (3) reframing policy problems as broadly social, rather than as solely scientific or technical. The obstacles that maize activists have faced in carrying out each of these efforts indicate that despite diverse and sophisticated engagements between social movements and the scientific field, scientization remains a significant institutional barrier to democratizing agricultural governance. (shrink)