Richard Anthony Jefferson

Richard Jefferson

Richard Jefferson, 2010

Richard Jefferson, 2010
Born Richard Anthony Jefferson
Residence Australia
Citizenship United States of America; Australia
Nationality United States of America; Australia
Institutions
Alma mater
Thesis DNA Transformation of Caenorhabditis elegans Development and Application of a New Gene Fusion System (Cloning, Chimeric, Sequence) (1985)
Doctoral advisor David I. Hirsh, William B. Wood
Known for
Notable awards Scientific American 50
Website
www.cambia.org

Richard Anthony Jefferson (born 1956) is an American-born molecular biologist and social entrepreneur who developed the widely used reporter gene system GUS,[3] conducted the world's first biotech crop release, proposed the Hologenome theory of evolution, pioneered Biological Open Source and founded The Lens. He is founder of the social enterprise Cambia and a Professor of Biological Innovation at the Queensland University of Technology. In 2003 he was named by Scientific American as one of the world's 50 most influential technologists, and is renowned for his work on making science-enabled innovation more widely accessible.[4][5] He was profiled in 'Open & Shut: The Basement Interviews',[6] and other major media, including in an Economist Feature 'Grassroots Innovator' in 2001.[7]

Education

Born in Santa Cruz, California, Jefferson studied at the University of California, Santa Barbara at the College of Creative Studies, and obtained his BA (Molecular Genetics) in 1978. He then moved to the University of Colorado Boulder for his Ph.D., where he first developed the GUS reporter system, isolating, sequencing and characterizing the first microbial glucuronidase,[3][8] and creating transgenic technology for Caenorhabditis elegans [9]

Career

As a postdoctoral researcher he worked at the Plant Breeding Institute in Cambridge, England: there he adapted the GUS assay for the use in plants.[3] His GUS system was a breakthrough in plant molecular sciences, useful for the development of efficient transformation methods for crop plants, and cell and developmental biology. In 1986-87 he sent all the components of the GUS system (DNA and strains) together with a comprehensive users' manual to nearly a thousand labs worldwide, before publication, pioneering a biological open source paradigm and a rapid uptake of the technology. The GUS system and its novel mode of dissemination was said to be essential for development of transformation of the most important crops, including soybean, maize, cotton and rice. The work has been cited in the primary literature almost 15,000 times.,[10] and has been licensed by every major company in crop genetics.

During his postdoc in Cambridge, he also initiated and managed, with his colleague Michael W. Bevan, the world's first field release of a transgenic food crop (June 1, 1987), in Trumpington, near Cambridge, UK.[11][12] The planting date of the experiment was serendipitously one day before that of Monsanto, in Jerseyville, Illinois, which has been widely but incorrectly viewed as the first such trial.[13][14]

In 1989, driven by a need to see the tools of science more broadly accessible and more effectively used in complex environments, Jefferson joined the Food and Agriculture Organization of the United Nations (FAO) as senior scientist, the first molecular biologist in this position. Since then he traveled, worked and taught in many developing countries. He left the organization in 1991 to start a non-profit private social enterprise, Cambia. Cambia soon moved to Australia, due to Jefferson's involvement in the Asian rice biotechnology programs of the Rockefeller Foundation,[11] and the proximity to almost half the worlds agricultural population.

In September 1994, Jefferson first articulated the Hologenome Theory of Evolution, at a presentation at Cold Spring Harbor Laboratory, at a Symposium "A Decade of PCR" [15] This theory was developed from his molecular and genetic work on glucuronide metabolism by vertebrate-associated microbes, including the role of glucuronidases, sulfatases and other enzymes in modulating and effecting enterohepatic circulation of steroid hormones. The levels, ratios and timing of steroid hormone de-conjugation (activation) and resorption modulates virtually all aspects of vertebrate ontogeny, physiology and reproduction. The premise for his theory was that natural selection acts on the 'holobiont' comprising a 'scaffold genome' and myriad microbial constituents in diverse ecosystems, selecting for persistence of the set of genetically-encoded capabilities.

In January 1997, the hologenome theory was extended, informed by further work on the molecular genetics of enteric microbial glucuronide metabolism, to emphasize the central role of microbially-mediated hormone modulation (MHM) as an essential component of multi-cellularity and vertebrate biology. This led Jefferson to coin the term ecotherapeutics, or ecological therapeutics, stating that a major route to improved performance or health of animals or plants would be through the adjustment of microbial populations and their genetic capabilities (microbiota often now called the (microbiomes).[16]

The development of theory and its logic were also outlined in detail in his blog in 2007,[17] and summarized in a cover article Jan 9, 2013, by Carrie Arnold in New Scientist [18]

In 1999, Jefferson was appointed as Author-in-Chief to the United Nations Convention on Biological Diversity for the landmark study, submitted to the UN General Assembly, on the contentious genetic technology, colloquially called 'Terminator Technology'. In this study [19] he coined and defined the term GURT - Genetic Use Restriction Technology and its variants.

At Cambia, and with the initial funding and partnership with Rockefeller Foundation's agriculture program, Jefferson and the Cambia staff started to develop key new tools - including the pCambia vectors,[20] released in 1997, and which now are the most widely used plasmids in plant biotechnology.

The continuous distribution of thousands of these tools without restrictions throughout the world, the dozens of conducted training courses, and the newly invented open technologies advanced what would become the Biological Open Source initiative, formally launched in 2005. In that year Jefferson and colleagues published a landmark paper in Nature [21] in which they described a new biological open source invention, TransBacter.

Agrobacterium-mediated gene transfer was by far the most common tool for agricultural biotechnology, but due to complex and extensive patenting, and aggressive pursuit of dominant patents by Monsanto, the use of the tool was constrained to merely academic pursuits or by use of multinational corporations under license. Using Patent Lens - the most popular global open full-text patent search engine - founded by Jefferson and his colleague Carol Nottenburg in 1999 as CambiaIP Resource - Cambia published the world's first open patent landscape.[22] Using the evidence and clarity obtained from this patent landscape, Jefferson and his colleagues designed and created an effective alternative technology that would not be constrained by any of the existing patents (of which there were by then almost a thousand). The technology, called Transbacter involved using three taxs of benign plant-associated bacteria modified with the gene-transfer components from Agrobacterium, to efficiently transfer genes to diverse crop species. "Transbacter" was made available under the first BiOS (Biological Open Source) license, for free to anyone and sent to hundreds of labs worldwide, and was licensed by public sector, small enterprise and multinationals under open principles, with commitments to share improvements with other licensees. The open patent landscape, initially authored by patent experts Nottenburg and Carolina Roa-Rodriguez and later updated by several other Cambia staff, in addition to many other landscapes serve as prototypes of Jefferson's subsequent initiative; open Innovation Cartography [23]

In 2009, with funding from the Bill & Melinda Gates Foundation, The Lemelson Foundation and the Gordon & Betty Moore Foundation, Jefferson moved with part of Cambia to the Queensland University of Technology (QUT) in Brisbane, Australia, as Professor of Science, Technology & Law, to direct the global activities on open Innovation Cartography.[24]

Known also for his expertise in intellectual property, Jefferson remains active in the promotion of open source biological innovation which has been covered extensively by global media.[25] He served on the World Economic Forum's Global Agenda Council on Intellectual Property for four years, and is on the WEF's Global Agenda Council on the Economics of Innovation. In 2013 Cambia launched The Lens[26] to replace the older Patent Lens and enable broader innovation-focused navigation platforms. Jefferson is considered a global leader in social entrepreneurship and is an Outstanding Social Entrepreneur of the Schwab Foundation,[27] and a plenary speaker at the Skoll World Forum.[28]

References

  1. Jefferson, R. A. (1987). "Assaying chimeric genes in plants: The GUS gene fusion system". Plant Molecular Biology Reporter 5 (4): 387–405. doi:10.1007/BF02667740.
  2. Jefferson, R. A. (1989). "The GUS reporter gene system". Nature 342 (6251): 837–8. doi:10.1038/342837a0. PMID 2689886.
  3. 1 2 3 Jefferson, R. A.; Kavanagh, T. A.; Bevan, M. W. (1987). "GUS fusions: Beta-glucuronidase as a sensitive and versatile gene fusion marker in higher plants". The EMBO Journal 6 (13): 3901–7. PMC 553867. PMID 3327686.
  4. Scientific American Website: The 2003 Scientific American 50 List of Winners , URL accessed on 30 May 2006
  5. Richard Anthony Jefferson's publications indexed by Google Scholar, a service provided by Google
  6. http://poynder.blogspot.com/2006/09/interview-with-richard-jefferson.html
  7. http://www.economist.com/node/885178
  8. Jefferson, R. A.; Burgess, S. M.; Hirsh, D. (1986). "Beta-Glucuronidase from Escherichia Coli as a Gene-Fusion Marker". Proceedings of the National Academy of Sciences 83 (22): 8447–8451. doi:10.1073/pnas.83.22.8447. PMC 386947. PMID 3534890.
  9. Jefferson, Richard A.; Klass, Michael; Wolf, Nurit; Hirsh, David (1987). "Expression of Chimeric Genes in Caenorhabditis Elegans". Journal of Molecular Biology 193 (1): 41–46. doi:10.1016/0022-2836(87)90624-3.
  10. https://scholar.google.com.au/citations?user=VVJ_j-cAAAAJ&hl=en
  11. 1 2 Jefferson, R. (2006). "Science as Social Enterprise: The CAMBIA BiOS Initiative". Innovations: Technology, Governance, Globalization 1 (4): 13–44. doi:10.1162/itgg.2006.1.4.13.
  12. Jefferson, Richard A. “New Approaches for Agricultural Molecular Biology: From Single Cells to Field Analysis.” Stadler Genetics Symposia Series (1990): 365–400. doi:10.1007/978-1-4684-7047-5_20.
  13. 2001, E Simanis & S. Hart, World Resources Institute Case Study, http://pdf.wri.org/bell/case_1-56973-475-5_full_version_a_english.pdf
  14. Archives of the Office of Technology Assessment (OTA) https://www.princeton.edu/~ota/disk2/1988/8816/881609.PDF
  15. Number 6 in a series of 7 VHS recordings, 'A Decade of PCR: Celebrating 10 Years of Amplification,' released by Cold Spring Harbor Laboratory Press, 1994. ISBN 0-87969-473-4.
  16. Jefferson, Richard A et al.. (1997). Molecular genetics of the E. coli gus operon: Medical and evolutionary implications for glucuronide and xenobiotic metabolism. 14th Congress of the South African Society of Biochemistry and Molecular Biology in Grahamstown, South Africa. Zenodo. 10.5281/zenodo.22796
  17. http://blogs.cambia.org/raj/2007/09/06/the-hologenome-hologenomics/
  18. "The hologenome: A new view of evolution". New Scientist 217: 30–34. doi:10.1016/s0262-4079(13)60115-3.
  19. https://www.cbd.int/doc/meetings/sbstta/sbstta-04/official/sbstta-04-09-rev1-en.pdf
  20. http://www.researchgate.net/post/Why_do_most_of_the_people_select_pCambia_vectors_for_cloning_in_transgenic_plants
  21. Broothaerts, Wim, Heidi J. Mitchell, Brian Weir, Sarah Kaines, Leon M. A. Smith, Wei Yang, Jorge E. Mayer, Carolina Roa-Rodríguez, and Richard A. Jefferson. “Gene Transfer to Plants by Diverse Species of Bacteria.” Nature 433, no. 7026 (February 10, 2005): 629–633. doi:10.1038/nature03309.
  22. http://www.cambia.org/daisy/AgroTran/835.html
  23. http://grist.org/food/a-16th-century-dutchman-can-tell-us-everything-we-need-to-know-about-gmo-patents/
  24. http://blogs.cambia.org/raj/2011/01/10/innovation-cartography-mapping-and-navigating-the-landscape/
  25. Herrera, S. (2005). "Profile: Richard Jefferson". Nature Biotechnology 23 (6): 643. doi:10.1038/nbt0605-643.
  26. http://www.lens.org
  27. http://www.schwabfound.org/sf/SocialEntrepreneurs/Profiles/index.htm?sname=129191
  28. http://skollworldforum.org/contributor/richard-jefferson/
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