Feb. 14, 2017

FOR IMMEDIATE RELEASE

With Stringent Oversight, Heritable Germline Editing Clinical Trials Could One Day Be Permitted for Serious Conditions; Non-Heritable Clinical Trials Should Be Limited to Treating or Preventing Disease or Disability at This Time 

WASHINGTON – Clinical trials for genome editing of the human germline – adding, removing, or replacing DNA base pairs in gametes or early embryos – could be permitted in the future, but only for serious conditions under stringent oversight, says a new report from the National Academy of Sciences and the National Academy of Medicine.  The report outlines several criteria that should be met before allowing germline editing clinical trials to go forward.  Genome editing has already entered clinical trials for non-heritable applications, but should be allowed only for treating or preventing diseases or disabilities at this time.

Genome editing is not new.  But new powerful, precise, and less costly genome editing tools, such as CRISPR/Cas9, have led to an explosion of new research opportunities and potential clinical applications, both heritable and non-heritable, to address a wide range of human health issues.  Recognizing the promise and the concerns related to this technology, NAS and NAM appointed a study committee of international experts to examine the scientific, ethical, and governance issues surrounding human genome editing.

Human genome editing is already widely used in basic research and is in the early stages of development and trials for clinical applications that involve non-heritable (somatic) cells.  These therapies affect only the patient, not any offspring, and should continue for treatment and prevention of disease and disability, using the existing ethical norms and regulatory framework for development of gene therapy.  Oversight authorities should evaluate safety and efficacy of proposed somatic applications in the context of the risks and benefits of intended use.

However, there is significant public concern about the prospect of using these same techniques for so-called “enhancement” of human traits and capacities such as physical strength, or even for uses that are not possible, such as improving intelligence.  The report recommends that genome editing for enhancement should not be allowed at this time, and that broad public input and discussion should be solicited before allowing clinical trials for somatic genome editing for any purpose other than treating or preventing disease or disability. 

“Human genome editing holds tremendous promise for understanding, treating, or preventing many devastating genetic diseases, and for improving treatment of many other illnesses,” said Alta Charo, co-chair of the study committee and Sheldon B. Lubar Distinguished Chair and Warren P. Knowles Professor of Law and Bioethics, University of Wisconsin-Madison.  “However, genome editing to enhance traits or abilities beyond ordinary health raises concerns about whether the benefits can outweigh the risks, and about fairness if available only to some people." 

Germline genome editing, in contrast, is contentious because genetic changes would be inherited by the next generation.  Many view germline editing as crossing an “ethically inviolable” line, the report says.  Concerns raised include spiritual objections to interfering with human reproduction to speculation about effects on social attitudes toward people with disabilities to possible risks to the health and safety of future children.  But germline genome editing could provide some parents who are carriers of genetic diseases with their best or most acceptable option for having genetically related children who are born free of these diseases. 

Heritable germline editing is not ready to be tried in humans.  Much more research is needed before it could meet the appropriate risk and benefit standards for clinical trials.  The technology is advancing very rapidly, though, making heritable genome editing of early embryos, eggs, sperm, or precursor cells in the foreseeable future “a realistic possibility that deserves serious consideration,” the report says.  Although heritable germline genome editing trials must be approached with caution, the committee said, caution does not mean prohibition.

At present, heritable germline editing is not permissible in the United States, due to an ongoing prohibition on the U.S. Food and Drug Administration's ability to use federal funds to review “research in which a human embryo is intentionally created or modified to include a heritable genetic modification.”  A number of other countries have signed an international convention that prohibits germline modification.

If current restrictions are removed, and for countries where germline editing would already be permitted, the committee recommended stringent criteria that would need to be met before going forward with clinical trials.  They include: (1) absence of reasonable alternatives; (2) restriction to editing genes that have been convincingly demonstrated to cause or strongly predispose to a serious disease or condition; (3) credible pre-clinical and/or clinical data on risks and potential health benefits; (4) ongoing, rigorous oversight during clinical trials; (5) comprehensive plans for long-term multigenerational follow-up; (6) continued reassessment of both health and societal benefits and risks, with wide-ranging, ongoing input from the public; and (7) reliable oversight mechanisms to prevent extension to uses other than preventing a serious disease or condition.

Policymaking surrounding human genome editing applications should incorporate public participation, and funding of genome editing research should include support to study the socio-political, ethical, and legal aspects and evaluate efforts to build public communication and engagement on these issues.

The report recommends a set of overarching principles that should be used by any nation in governing human genome editing research or applications:

“Genome editing research is very much an international endeavor, and all nations should ensure that any potential clinical applications reflect societal values and be subject to appropriate oversight and regulation,” said committee co-chair Richard Hynes, Howard Hughes Medical Institute Investigator and Daniel K. Ludwig Professor for Cancer Research, Massachusetts Institute of Technology.  “These overarching principles and the responsibilities that flow from them should be reflected in each nation’s scientific community and regulatory processes.

Such international coordination would enhance consistency of regulation.”

The study was funded by the Defense Advanced Research Projects Agency, the Greenwall Foundation, the John D. and Catherine T. MacArthur Foundation, U.S. Department of Health and Human Services, U.S. Food and Drug Administration, and the Wellcome Trust, with additional support from the National Academies’ Presidents’ Circle Fund and the National Academy of Sciences W.K. Kellogg Foundation Fund.  The National Academy of Sciences and the National Academy of Medicine are private, nonprofit institutions that, along with the National Academy of Engineering, provide independent, objective analysis and advice to the nation to solve complex problems and inform public policy decisions related to science, technology, and medicine.  The Academies operate under an 1863 congressional charter to the National Academy of Sciences, signed by President Lincoln.  For more information, visit www.national-academies.org.

Copies of Human Genome Editing: Science, Ethics, and Governance are available at www.nap.edu or by calling 202-334-3313 or 1-800-624-6242.  Reporters may obtain a copy from the Office of News and Public Information (contacts listed above). 

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NATIONAL ACADEMY OF SCIENCES
and
NATIONAL ACADEMY OF MEDICINE
 
Committee on Human Gene Editing: Scientific, Medical, and Ethical Considerations

 
Alta Charo1 (co-chair)
Sheldon B. Lubar Distinguished Chair and Warren P. Knowles Professor of Law and Bioethics
University of Wisconsin
Madison

Richard O. Hynes1,2 (co-chair)
Investigator
Howard Hughes Medical Institute, and
Daniel K. Ludwig Professor for Cancer Research
Massachusetts Institute of Technology
Cambridge

David W. Beier
Managing Director
Bay City Capital
San Francisco

Ellen Wright Clayton1
Craig Weaver Professor of Pediatrics, and
Professor of Law
Vanderbilt University
Nashville, Tenn.

Barry S. Coller1,2
David Rockefeller Professor of Medicine,
Physician in Chief, and
Head
Allen and Frances Adler Laboratory of Blood and Vascular Biology
Rockefeller University
New York City

John H. Evans
Professor
University of California
San Diego

Juan Carlos Izpisua Belmonte
Professor
Gene Expression Laboratory
Salk Institute for Biological Studies
La Jolla, Calif.

Rudolf Jaenisch1,2
Professor of Biology
Massachusetts Institute of Technology
Cambridge

Jeffrey Kahn1
Andreas C. Dracopoulos Director
Johns Hopkins Berman Institute of Bioethics
Johns Hopkins University
Baltimore

Ephrat Levy-Lahad
Director
Fuld Family Department of Medical Genetics
Shaare Zedek Medical Center
Faculty of Medicine
Hebrew University of Jerusalem
Jerusalem

Robin Lovell-Badge
Senior Group Leader
Laboratory of Stem Cell Biology and Developmental Genetics
The Francis Crick Institute
London

Gary Marchant
Regents’ Professor of Law
Arizona State University
Tempe

Jennifer Merchant
University Professor
Université de Paris II (Panthéon-Assas)
Issy-les-Moulineaux, France

Luigi Naldini
Professor of Cell and Tissue Biology and of Gene and Cell Therapy
San Raffaele University, and
Director
San Raffaele Telethon Institute for Gene Therapy
Milan

Duanqing Pei
Professor and Director General
Guangzhou Institute of Biomedicine and Health
Chinese Academy of Sciences
Guangzhou, China

Matthew Porteus
Associate Professor of Pediatrics
Stanford School of Medicine
Stanford, Calif.

Janet Rossant2
Senior Scientist and Chief of Research Emeritus
Hospital for Sick Children
University of Toronto
Toronto

Dietram A. Scheufele
John E. Ross Professor in Science Communication and Vilas Distinguished Achievement Professor
University of Wisconsin
Madison

Ismail Serageldin2
Founding Director
Bibliotheca Alexandrina
Alexandria, Egypt

Sharon Terry
President and CEO
Genetic Alliance
Washington, D.C.

Jonathan Weissman2
Professor
Department of Cellular and Molecular Pharmacology
University of California
San Francisco

Keith R. Yamamoto1,2
Vice Chancellor for Science Policy and Strategy
University of California
San Francisco

STAFF

Katie Bowman
Study Director

1Member, National Academy of Medicine
2Member, National Academy of Sciences