Researchers Engineer Plants for Far Higher Photosynthesis Efficiency

Total Page:16

File Type:pdf, Size:1020Kb

Researchers Engineer Plants for Far Higher Photosynthesis Efficiency A genetically engineered tobacco plant developed by U.S. and U.K. scientists using genes from blue-green algae could lead the way to improving yields of major global crops by up to 60%. The research was aimed at speeding up the process of photosynthesis, whereby plants convert sunlight, water and carbon dioxide into oxygen and sugar. Rubisco is the enzyme in plants responsible for fixing carbon into molecules that form the building blocks of plants, but it is considered to be extremely inefficient as it often reacts with oxygen instead of CO2 - one of the reasons why it is likely the most abundant protein on the planet. What the scientists did was borrow a faster Rubisco enzyme from blue-green algae, or cyanobacterium, and put it into a tobacco plant. Tobacco plants are considered to be a common model organism for genetic engineering research. Teams led by Cornell University plant geneticist Maureen Hanson in the U.S. and Rothamsted Research plant physiologist Martin Parry in the U.K, worked in equal measure on the research, using Cornell's expertise in genetic engineering and Rothamsted's expertise in enzyme biochemistry. The researchers transferred the cyanobacterium Rubisco into chloroplasts of the tobacco plant. In some of the plants the researchers also added a bacterial protein that was thought to help Rubisco fold properly, while in others they added a bacterial protein that structurally supported Rubisco. Both lines of tobacco were able to use the Rubisco for photosynthesis, and both reacted with carbon dioxide and created new molecules faster than normal tobacco. Exciting possibility Hanson explained that although this development was an important step for enhancing photosynthesis in crops, there was much work still to be done. She added the newly engineered tobacco plant was 'not an improvement' over the natural plant as it did not have the oxygen-repelling bacterial microcompartments FreshFruitPortal.com called carboxysomes needed for the GM plants to be of any use in natural conditions. "The carboxysome normally encloses the enzyme, protects it from oxygen and increases the amount of carbon dioxide right around the enzyme so it can work faster," Hanson told www.freshfruitportal.com. As the scientists were not able to use the carboxysomes, the genetically modified tobacco plants had to be grown in special chambers with a CO2 concentration 20 times higher than normal in order for photosynthesis to occur more quickly. "If we were to include this carboxysome - which is what we're trying to do now - then the atmosphere right around the Rubisco enzyme would be very very high in CO2, and so photosynthesis could proceed more rapidly," she said. "And that's why everyone's interested in doing this." Hanson said another group led by Dr. Stephen Long at the University of Illinois had modeled a computer simulation of the potential effects on crop yield if photosynthesis efficiency were to be increased in this manner. Their calculations indicated it could be anywhere from 36-60% higher. "So that's why this is an exciting possibility, but we haven't finished the job - we have to get that carboxysome in there," she said. The increase in yield is all the more important as many plant breeders are said to be reaching the end of their ability to use natural genetic variation to improve yields in some major global crops like rice and wheat Hanson said it therefore looked like using modern genetic modification technology could be the best answer to the question of how to feed a rapidly growing world population. GM technology 'absolutely necessary' In order to make the carboxysomes in the genetically modified tobacco plants, a further 'six or seven' genes will need to be transferred into the tobacco plant chloroplast. "That's what we're working on now - we're attempting to put all the genes in," Hanson said. "It's a little bit trickier because you need to have not only the genes in there, but you have to FreshFruitPortal.com have them controlled properly in order to make the right amount of protein." Hanson said researchers might be able to put this mechanism into one major crop 'in a decade', but one of the main obstacles to it being adopted on a global scale would be people's reservations over GM technology. "I'm hoping there will be increasing acceptance of genetically modified food as the people learn more about it and have some of the frankly unreasonable fears about it dispelled through education," she said. "I don't see any way we can feed the world without using this technology. I think really it's absolutely going to be necessary, and when it becomes necessary then I think acceptance might increase." Photo: Wikimedia Creative Commons www.freshfruitportal.com FreshFruitPortal.com.
Recommended publications
  • Transgenic Maize Lines with Cell-Type Specific Expression of Fluorescent Proteins in Plastids
    University of Nebraska - Lincoln DigitalCommons@University of Nebraska - Lincoln Agronomy & Horticulture -- Faculty Publications Agronomy and Horticulture Department 2010 Transgenic maize lines with cell-type specific expression of fluorescent proteins in plastids Amir Sattarzadeh Cornell University, Ithaca Jonathan Fuller Boyce Thompson Institute for Plant Research Salvador Moguel University of Nebraska-Lincoln & Union College, Lincoln Katia Wostrikoff Boyce Thompson Institute for Plant Research & IBPC Shirley Sato University of Nebraska-Lincoln See next page for additional authors Follow this and additional works at: https://digitalcommons.unl.edu/agronomyfacpub Part of the Agricultural Science Commons, Agriculture Commons, Agronomy and Crop Sciences Commons, Botany Commons, Horticulture Commons, Other Plant Sciences Commons, and the Plant Biology Commons Sattarzadeh, Amir; Fuller, Jonathan; Moguel, Salvador; Wostrikoff, Katia; Sato, Shirley; Covshoff, Sarah; Clemente, Tom; Hanson, Maureen; and Stern, David, "Transgenic maize lines with cell-type specific expression of fluorescent proteins in plastids" (2010). Agronomy & Horticulture -- Faculty Publications. 1372. https://digitalcommons.unl.edu/agronomyfacpub/1372 This Article is brought to you for free and open access by the Agronomy and Horticulture Department at DigitalCommons@University of Nebraska - Lincoln. It has been accepted for inclusion in Agronomy & Horticulture -- Faculty Publications by an authorized administrator of DigitalCommons@University of Nebraska - Lincoln. Authors
    [Show full text]
  • All in the Family: Is ME/CFS Inherited?
    SPRING 2018 All in the Family: Is ME/CFS Inherited? The quest to understand We’ve long understood that physical cost. A task that was science fiction characteristics are be inherited and just a few short years ago. In the genetics and inherited that these same genes also contrib- near future, gene editing will allow traits is possibly one ute to our overall health and well- us to correct ‘faulty’ genes associ- ness. This includes the development ated with a range of human genetic of the oldest and most and progression of various diseases. disorders. exciting scientific Today, we know that genetic muta- tions can cause complex diseases, When discussing a complex disease endeavors. It is also a from diabetes to cancer, and that like ME/CFS, particularly a sensi- subject within ME/CFS genetic ‘predisposition’ can be a risk tive topic like inherited traits, it factor that shapes our health. helps to be mindful of at least three that remains poorly broad categories: classical genetics, understood. Our understanding of genetics has epigenetics, and pathogenic-host grown substantially. We can now interactions. » to page 4 Since people with ME/CFS can be read, map, interpret, and modify found within the same family more the building blocks that make up often than random association our DNA. Scientific advances now INSIDE would dictate, is there a possible allow us to identify genetic irregu- 2 SMCI This Quarter: A Summary of genetic component to ME/CFS? larities quickly and for a reasonable Our Work 5 SMCI Welcomes Two New Members to Its Board of Directors 6 What’s in a Definition? Finding a Common Language for ME/CFS 8 PEM: It’s Time to Retire the Term 9 Dr.
    [Show full text]
  • Dr. Maureen Hanson: from Plant Biology to ME/CFS Champion (Cont’D)
    RESEARCH SOLVE ME/CFS INITIATIVE RESEARCH ADVISORY COUNCIL Anthony Komaroff, MD Dr. Maureen Hanson: Harvard Medical School From Plant Biology to Maureen Hanson, PhD ME/CFS Champion Cornell University Susan Levine, MD DR. MAUREEN HANSON is the Liberty Hyde Bailey Professor in the Depart- Medical Offce of Susan M. Levine, MD ment of Molecular Biology & Genetics at Cornell University and a member of the Solve ME/CFS Initiative (SMCI) Research Advisory Council (RAC). Notably, she is directing a National Institutes of Health (NIH) funded myalgic enceph- Jose Montoya, MD Stanford University alomyelitis/chronic fatigue syndrome (ME/CFS) Collaborative Research Center Medical Center recently established at Cornell following a competitive grant process. Over the next fve years, the Center will work on three parimary research projects and Peter Rowe, MD work cooperatively with a network of three other ME/CFS centers. We recently Johns Hopkins sat down to speak with Dr. Hanson about her work. Sheila Stewart, PhD If you had a magic wand, what are the top three barriers you would Washington University School remove frst in order to accelerate the discovery process or improve of Medicine the lives of patients? Tarek Absi, MD Despite recent increases in funds for ME/CFS at NIH, an important barrier is Vanderbilt University Medical the relatively modest amount of NIH support devoted to grant proposals to Center study ME/CFS. The funding rates of investigator-initiated proposals at most NIH Institutes is less than 20%. If proposals to study HIV and AIDS had been Daan Archer, MBA, MSc Massachussetts Institute of this low during the AIDS epidemic, many more years would have been need- Technology Media Lab ed to develop life-saving drugs.
    [Show full text]
  • PLENARY SPEAKERS for PLANT CANADA 2019 ALL PLENARY TALKS WILL BE in ROZANSKI HALL Room 104
    PLANT CANADA 2019 Time Monday July 8th Tuesday July 9th Wednesday July 10th Place Room: Rozanski 104 Room: Rozanski 104 Room: Rozanski 104 8-8:30 Coffee-break (concourse) Coffee-break (concourse) Coffee-break (concourse) Session Plant Biotechnology Agronomy Managing Plant Disease in Horticulture Chairs Dr. Rima Menassa & Dr. Helen Booker Dr. Lone Buchwaldt & Dr. Abdelali Hannoufa Dr. Valerie Gravel 8:30am Dr. Maureen Hanson Dr. D. Brian Fowler Dr. Mary Ruth McDonald Cornell University, NY University of Saskatchewan, SK University of Guelph, ON Improving photosynthesis in Winter wheat production in the Billions, trillions and C3 plants high winter stress climate of quadrillions: The challenge of western Canada managing clubroot on canola – An experiment in crop adaptation and vegetables 9:20am Dr. Bing Yang Dr. Clarence J Swanton Dr. Richard Bélanger University of Missouri, MO University of Guelph, ON Université Laval, Québec, QC Genome editing enables Plant competition and the A unique interaction with a disease resistance in rice physiology of fear biocontrol agent alters the parasitic activity of powdery mildews on plants 10:10am Dr. Leslie Sieburth Dr. Jaswinder Singh Dr. Diane G.O. Saunders University of Utah, UT McGill University, QC John Innes Centre, UK CSPB C.D. Nelson Award Address: Beyond transcription factors: New paradigms in the genetic The wheat-rust conflict: Shifty A degrading story of gene regulation of pre- and post- harvest enemies and the long reach of expression control grain germination in cereals genomics 11:00am Lunch at Creelman Hall Lunch at Creelman Hall Lunch at Creelman Hall Session Root evolution, Development and Function Chairs Dr.
    [Show full text]
  • In-Depth Analysis of the Plasma Proteome in ME/CFS Exposes Disrupted Ephrin-Eph and Immune System Signaling
    proteomes Article In-Depth Analysis of the Plasma Proteome in ME/CFS Exposes Disrupted Ephrin-Eph and Immune System Signaling Arnaud Germain , Susan M. Levine and Maureen R. Hanson * Department of Molecular Biology and Genetics, Cornell University, Ithaca, NY 14853, USA; [email protected] (A.G.); [email protected] (S.M.L.) * Correspondence: [email protected]; Tel.: +1-607-254-4833 Abstract: Myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) is a disabling disease with worldwide prevalence and limited therapies exclusively aimed at treating symptoms. To gain insights into the molecular disruptions in ME/CFS, we utilized an aptamer-based technology that quantified 4790 unique human proteins, allowing us to obtain the largest proteomics dataset yet available for this disease, detecting highly abundant proteins as well as rare proteins over a nine- log dynamic range. We report a pilot study of 20 ME/CFS patients and 20 controls, all females. Significant differences in the levels of 19 proteins between cohorts implicate pathways related to the extracellular matrix, the immune system and cell–cell communication. Outputs of pathway and cluster analyses robustly highlight the ephrin pathway, which is involved in cell–cell signaling and regulation of an expansive variety of biological processes, including axon guidance, angiogenesis, epithelial cell migration, and immune response. Receiver Operating Characteristic (ROC) curve analyses distinguish the plasma proteomes of ME/CFS patients from controls with a high degree of accuracy (Area Under the Curve (AUC) > 0.85), and even higher when using protein ratios (AUC up to 0.95), that include some protein pairs with established biological relevance.
    [Show full text]
  • The Many Legacies of ASPB by SALLY MACKENZIE University of Nebraska–Lincoln
    May/June 2017 • Volume 44, Number 3 p. 4 p. 14 p. 21 ASPB Announces Jenna Gallegos ASPB Welcomes 2017 Award Awarded ASPB/AAAS Winnie Nham as Winners Mass Media New Education Fellowship Coordinator THE NEWSLETTER OF THE AMERICAN SOCIETY OF PLANT BIOLOGISTS President’s Letter The Many Legacies of ASPB BY SALLY MACKENZIE University of Nebraska–Lincoln FEBRUARY 14–17, 2018 t ASPB, so much has If ASPB is to continue its FEBRUARY 14–17, 2018 TUCSON,TUCSON, AZ AZ changed over the leadership role in plant biology, past few years. Our additional financial resources HILTON EL CONQUISTADOR RESORT A HILT ON EL CONQUISTADOR RESORT flagship journals are now will be needed to sustain these online-only and offer open activities. Library subscriptions access options; we welcome continue to be the largest reve- the initiation of our new jour- nue source for ASPB. But pres- nal, Plant Direct; and ASPB sure from governments around is set to better interconnect the world to implement open its members with the larger access publication of publicly plant science community funded research, coupled with by way of the Plantae digital declining congressional support ecosystem. The Society stands Sally Mackenzie for basic research and state behind a new annual meeting support for public universities, in phenomics, and it is playing a growing role has influenced those revenues, compelling in helping support meetings for a number the Society to seek other ways to ensure it of plant science groups. ASPB has recently remains fiscally sound. Consequently, ASPB expanded its outreach activities to represent is creating a mix of revenue sources that will and inform plant scientists, sponsoring the allow it to continue its many good works.
    [Show full text]
  • Hacked Photosynthesis Could Boost Crop Yields Algal Enzyme Can Speed up Rate at Which Plants Make Food
    NATURE | NEWS Hacked photosynthesis could boost crop yields Algal enzyme can speed up rate at which plants make food. Heidi Ledford 17 September 2014 chain45154/Moment/Getty Rice is one of the crops that could increase their yields by converting solar energy more efficiently. It is difficult to find fault with a process that can create food from sunlight, water and air, but for many plants, there is room for improvement. Researchers have taken an important step towards enhancing photosynthesis by engineering plants with enzymes from blue-green algae that speed up the process of converting carbon dioxide into sugars. The results, published today in Nature1, surmount a daunting hurdle on the path to boosting plant yields — a goal that is taking on increasing importance as the world’s population grows. “With the limited ability to increase land use for agriculture, there’s a huge interest in trying to improve yield across all the major crops,” says Steven Gutteridge, a research fellow at chemical firm DuPont’s crop-protection division in Newark, Delaware. Researchers have long wanted to increase yields by targeting Rubisco, the enzyme responsible for converting carbon dioxide into sugar. Rubisco is possibly the most abundant protein on Earth, and can account for up to half of all the soluble protein found in a leaf. But one reason for its abundance is its inefficiency: plants produce so much Rubisco in part to compensate for its slow catalysis. Some have estimated that tinkering with Rubisco and ways to boost the concentration of carbon dioxide around it could generate up to a 60% increase2 in the yields of crops such as rice and wheat.
    [Show full text]
  • MBG Fall 2019- Spring 2020 Seminar Series Listing
    MBG Fall 2019 Seminar Series 4pm/G-10 Biotechnology Building 08.23 Jay Hirsch: Professor of Biology, Director of Undergraduate Program in Neuroscience, University of Virginia Title: Dopamine dependent regulatory responses in flies and mice Host: Eric Alani and Mariana Wolfner Website: http://bio.as.virginia.edu/people/ih6u 08.30 Lan Huang: Professor, Department of Physiology & Biophysics, UC Irvine Title: “Cross-linking Mass Spectrometry for Defining Protein Interactions and Structures” Host: Haiyuan Yu Website: https://webfiles.uci.edu/lanhuang/www/ 09.06 Philippe Soriano: Professor, Icahn School of Medicine at Mount Sinai Title: Untangling signaling specificity in development, one phosphate at a time Host: Marcos Simoes-Costa Website: https://www.mountsinai.org/profiles/philippe-m-soriano 09.20 Yuxin Mao: Associate Professor, Molecular Biology & Genetics, Cornell University Title: “Ubiquitin hijacking in bacterial pathogen-host interactions” Website: https://mbg.cornell.edu/people/yuxin-mao/ 09.27 Klaas Van Wijk: Professor in the Section of Plant Biology, School for Integrative Plant Science, Cornell University Title: Chloroplast Proteostasis and the Clp protease system Host: Maureen Hanson Website: https://plantbio.cals.cornell.edu/people/klaas-van-wijk/ 10.04 Eva Nogales: Howard Hughes Medical Institute investigator; a Professor of Biochemistry and Molecular Biology at the University of California, Berkeley; and Senior Faculty Scientist at the Lawrence Berkeley National Laboratory Title: “Visualization of key protein complexes in
    [Show full text]
  • Optimizing the Expression of Bacterial Cellulases in Chloroplast Transgenic Plants Dr
    Optimizing the Expression of Bacterial Cellulases in Chloroplast Transgenic Plants Dr. Maureen Hanson, Liberty Hyde Bailey Professor, Department of Molecular Biology Genetics, Cornell University ABSTRACT Enzymatic hydrolysis of biomass to fermentable sugars is a key step in the sustainable production of cellulosic ethanol. Efficient methods for enzyme synthesis are necessary to reduce the cost of bioethanol. Biosynthesis of biomass-degrading enzymes by feedstock plants could be part of an effective strategy for generation of bioenergy from lignocellulosic materials. Because high levels of various therapeutic proteins have been obtained through transformation of the chloroplast genome, we investigated what features of chloroplast transgenes are important for transgenic synthesis of cellulose- converting enzymes encoded by genes from the thermophilic bacterium Thermobifida fusca. We placed coding regions for an endoglucanase and beta-glucosidase under the control of a phage 5’ untranslated region, the plastid 16S rRNA promoter, and a plastid terminator, and introduced constructs into the tobacco chloroplast genome by particle bombardment. Sequences were fused at the 5’ end of the coding regions to express proteins carrying different 14 amino acid N-terminal fusions. In transgenic plants, the most effective transgenes resulted in plants that accumulated the enzymes to as much as 10-12% of total leaf soluble protein (TSP), while less than 0.3% TSP was obtained from leaves of plants carrying the least effective transgenes. Enzyme accumulation was stable during plant development. Endoglucanase could be purified on cellulose affinity columns and enzyme activity correlated well with protein quantification by immunoblot. The chloroplast-expressed β-glucosidase was active against cellobiose. This study demonstrates the feasibility of high-level chloroplast-based synthesis of biomass-degrading enzymes.
    [Show full text]
  • A Difficult Decision
    July/August 2021 • Volume 48, Number 4 p. 5 p. 6 p. 9 Yunde Zhao to Plant Synthetic Plant Scientists Become the Next Biology 2021 Elected to the 2021 Editor-in-Chief Class of the U.S. of Plant Physiology® September 25–27 National Academy of Sciences THE NEWSLETTER OF THE AMERICAN SOCIETY OF PLANT BIOLOGISTS President’s Letter 2021 ASPB Election Results A Difficult Decision any thanks to those members who BY MAUREEN McCANN took the time to vote earlier this ASPB President, National Renewable Energy Laboratory Msummer, and hearty congratula- tions to our newly elected Board members! Their new service roles for ASPB will begin on October 1, 2021, and you can look for more major focus of ballots are certified and information about them in the next issue of ASPB is science applies limits on access the ASPB News. Apolicy and how it to voting that have been impacts research funding, widely interpreted to target the pipeline of talent into marginalized communi- our labs, and regulatory ties, most recently by the practices. In the United U.S. Department of Justice. States, our Science Policy The passing of this law Committee engages on our was a challenge for ASPB. behalf with federal fund- After staff members and ing agencies and legislators the Program Committee from both parties to raise visited the city in early awareness of, and advocate March 2020, the ASPB for, the critical importance Board of Directors (BoD) of plant biology. ASPB does voted to approve the Incoming President-elect Gustavo MacIntosh not and cannot engage in partisan politics.
    [Show full text]
  • 2Nd International Conference on Plant Synthetic Biology, Bioengineering, and Biotechnology
    2nd International Conference on Plant Synthetic Biology, Bioengineering, and Biotechnology NOVEMBER 29 DECEMBER 1, 2018 HYATT REGENCY CLEARWATER BEACH RESORT AND SPA, CLEARWATER, FL Organized by the Society for Biological Engineering SPECIAL THANKS TO THIS YEAR’S SPONSORS GOLD SILVER BRONZE TABLE OF CONTENTS Welcome Address ........................................................................................... 2 Conference Organizers .................................................................................. 3 Technical Program ........................................................................................... 4 Poster Titles ...................................................................................................... 7 Keynote and Invited Speakers Biographies ................................................ 8 Oral Abstracts ................................................................................................12 Poster Abstracts .............................................................................................24 Code of Conduct ...........................................................................................28 TIPS FOR A SUCCESSFUL MEETING Say hello to everyone. You might make someone’s day. Introduce yourself to people you don’t know. They may be your next good friends. Stop and smile. You will brighten the room considerably. Be understanding. Everybody makes mistakes. Help those with less experience. We were all novices at some point. Respect others. We all have something valuable
    [Show full text]
  • SMCI THIS QUARTER: a Summary of Our Work in Research, Advocacy and Beyond
    NEWS AND UPDATES SMCI THIS QUARTER: A Summary of Our Work in Research, Advocacy and Beyond RESEARCH: Engaging the entire ME/CFS community and accelerating the discovery of safe and effective treatments. • Three SMCI-funded researchers presented at the Second Annual Commu- nity Symposium on the Molecular Basis of ME/CFS at Stanford University, SMCI-directed Projects partner, Dr. Maureen Hanson (Cornell University, SMCI Research Advisory Council (RAC) member), and two Ramsay Award Program Researchers, Dr. Jarred Younger (University of Alabama at Bir- mingham, Ramsay 2016) and Dr. Jonas Bergquist (Uppsala University, Ramsay 2017). • SMCI’s Chief Scientific Officer, Dr. Sadie Whittaker, attended the Centers for Disease Control and Prevention (CDC) Roundtable on Medical Education and ME/CFS in Atlanta, GA. • Columbia University Mailman School of Public Health’s Center for Infection & Immunity was funded by SMCI to complete a study aiming to build on re- cent metabolomics analysis. We provided $50,000 to continue this compre- SMCI Director of Advocacy and Community Relations Emily Taylor and hensive deep-dive, uncovering evidence for a biomarker signature for ME/ Director of Research Programs Allison CFS. Research results are anticipated in late 2019. Ramiller at Genetic Alliance’s “People • SMCI funded an extension of the 2016 Ramsay Class project led by Dr. Ger- Driven” conference aldine (Jo) Cambridge (University College London). To build on promising results that have been accepted for publication in Frontiers in Immunology. SOLVE ME/CFS INITIATIVE • Dr. Lubov Nathanson, funded by SMCI’s Ramsay program, is leading a proj- PROFESSIONAL STAFF ect to look at epigenetic changes in specific immune cell subtypes.
    [Show full text]