A new POSTnote from The Parliamentary Office of Science and Technology considers the different intellectual property rights approaches available to plant breeders. Download PDF (392kB) >>

Plant breeding is an essential practice in agriculture and horticulture. Plant breeders may seek intellectual property rights (IPR) over plant varieties and breeding techniques to protect their investment in research. This POSTnote considers the different IPR approaches available to plant breeders.

Guest post by Olivia Lala, Publicity Officer, Cambridge University Synthetic Biology Society

A team of undergraduates including previous iGEM team members have just started a new society, the Cambridge University Synthetic Biology Society (CUSBS). Synthetic Biology (SynBio) is an emerging inter-disciplinary research field at the interface between engineering and the life sciences. Having secured £5000 in funding for the first year the society will focus on two student-led projects. The projects will provide the opportunity to get hands experience doing bio-hardware. As well as this there will be termly talks on new advances in the field given by experts and opportunities to do outreach at local schools.

The first event organised by the society and the Biological Society (BioSoc) included a talk by Dr Tom Ellis on Synthetic Biology - from synthetic genes to synthetic genomes. They are now looking for new members who would be interested in joining, anyone is welcome! A first taster session is being organised for the 23 January - more details to follow.

Anyone interested should email cusbs-executive@srcf.net

To apply: Please send a CV with covering note and ask your tutor or research supervisor to email a short recommendation to: Jenny Molloy Email: jcm80@cam.ac.uk

The new field of Synthetic Biology is based upon the adoption of (i) engineering principles of abstraction and modularity, (ii) computational tools from Systems Biology and (iii) new genetic engineering techniques and components - for the rational design and assembly of new biological systems. It is a practical subject, concerned with the construction of new living artifacts. The new interdisciplinary field is being propelled by the need for improved plant and microbial feedstocks, bioenergy sources, and new catalysts for bioprocessing. Synthetic Biology is seeing a rising tide of new scientific activities, research funding and commercial investment.

iGEM is an international undergraduate synthetic biology competition where student teams are given access to DNA parts from the Registry of Standard Biological Parts at the Massachusetts Institute of Technology (MIT). The aim is to use these and other new parts to design and construct new biological systems and operate them in living cells. (see: http://igem.org). Cambridge provided the first team from the UK (see: http://www.synbio.cam.ac.uk). Since 2005, there has been wide interdisciplinary support for a University of Cambridge team in the iGEM competition. The competition provides a practical, laboratory based experience, with a focus on bottom-up design and assembly techniques, standardised biological components and cellular devices. This year sees the introduction of a new track for the engineering of plants in the competition. We are drawing together a team who can contribute in an interdisciplinary way to development of new DNA parts, quantitative methods and instrumentation for engineering of plant systems.

The team will be run jointly with the John Innes Centre, an independent, international centre of excellence in plant science and microbiology based in Norwich, with a mission to improve agriculture, the environment, human health and well-being, and engage with policy makers.

Participation in the iGEM competition offers:

1. Interdisciplinarity and teamwork. Students from Biology, Engineering, Computing and the Physical Sciences participate in the iGEM team.
2. Hands-on practical experience. The iGEM competition provides laboratory experience with the handling of synthetic biological systems to provide better grounding in practical skills for future project work.
3. Project and group based learning. Students share team work in laboratory work, biological design, project management and presentation.
4. Student exchange. In addition to promoting improved collaboration across Cambridge, participation provides opportunities for links with scientists at the John Innes Centre, collaboration and international exchange.
5. Lab resources. The iGEM team will have access to labs equipped for handling biological systems and construction of hardware, including 3D printing.
6. Open Instrumentation. Students will be able to work with Arduino and Raspberry Pi-based microcontrollers and interface these with optics, microelectronics and motors for DIY instrumentation.

Application details:

iGEM studentship funding will be available for up to 10 first and second year Cambridge undergraduates to allow participation in the competition. The competition will start on Monday, 27th June 2016, and will be based in the Department of Plant Sciences, University of Cambridge. The first two weeks of the competition will include a crashcourse in Plant Synthetic Biology, with brainstorming and practical exercises. The studentships will include a stipend of £180 per week for ten weeks, registration fees for the competition, exchange visits with the John Innes Centre, access to state-of-the-art laboratory facilities and workshops and attendance at the global iGEM Jamboree at Boston, USA in November 2016.

Faculty advisors are:

Jim Ajioka (Pathology), Alexandre Kabla (Engineering), Jim Haseloff (Plant Sciences) and George Lomonossoff (John Innes Centre).

For further information on the competition see http://www.igem.org.

From the John Innes Centre news feed and featuring OpenPlant scientists Professor Cathie Martin and Dr Yang Zhang.

Given the opportunity to drink fifty bottles of wine or eat one tomato, which would you choose?

Scientists at the John Innes Centre have found a way to produce industrial quantities of useful natural compounds efficiently, by growing them in tomatoes.

The compounds are phenylpropanoids like Resveratrol, the compound found in wine which has been reported to extend lifespan in animal studies, and Genistein, the compound found in soybean which has been suggested to play a role in prevention of steroid-hormone related cancers, particularly breast cancer. 

As a result of the research led by Dr Yang Zhang and Dr Eugenio Butelli working in Professor Cathie Martin’s lab at the John Innes Centre, one tomato can produce the same quantity of Resveratrol as exists in 50 bottles of red wine. One tomato has also produced the amount of Genistein found in 2.5kg of tofu.

Drs Zhang and Butelli have been studying the effect of a protein called AtMYB12 which is found in Arabidopsis thaliana, a plant found in most UK gardens and used as a model plant in scientific investigation. 

The protein AtMYB12 activates a broad set of genes involved in metabolic pathways responsible for producing natural compounds of use to the plant. The protein acts a bit like a tap to increase or reduce the production of natural compounds depending on how much of the protein is present. 

What was interesting about the effect of introducing this protein into a tomato plant was how it acted to both increase the capacity of the plant to produce natural compounds (by activating phenylpropanoid production) and to influence the amount of energy and carbon the plant dedicated to producing these natural compounds. In response to the influence of the AtMYB12 protein, tomato plants began to create more phenylpropanoids and flavanoids and to devote more energy to doing this in fruit.

Introducing both AtMYB12 and genes from plants encoding enzymes specific for making Resveratrol in grape and Genistein in legumes, resulted in tomatoes that could produce as much as 80mg of novel compound per gram of dry weight –demonstrating that industrial scale up is possible. 

Tomatoes are a high yielding crop – producing up to 500 tonnes per hectare in countries delivering the highest yields (FAOSTAT 2013) and require relatively few inputs. Production of valuable compounds like Resveratrol or Genistein in tomatoes could be a more economical way of producing them than relying on artificial synthesis in a lab or extracting them in tiny quantities from traditional plant sources (e.g., grapes, soybeans, etc.). The tomatoes can be harvested and juiced and the valuable compounds can be extracted from the juice. The tomatoes themselves could potentially become the source of increased nutritional or medicinal benefit. 

Professor Cathie Martin said:

“Our study provides a general tool for producing valuable phenylpropanoid compounds on an industrial scale in plants, and potentially production of other products derived from aromatic amino acids. Our work will be of interest to different research areas including fundamental research on plants, plant/microbe engineering, medicinal plant natural products, as well as diet and health research.”

Dr Yang Zhang, said:

“Medicinal plants with high value are often difficult to grow and manage, and need very long cultivation times to produce the desired compounds. Our research provides a fantastic platform to quickly produce these valuable medicinal compounds in tomatoes. Target compounds could be purified directly from tomato juice. We believe our design idea could also be applied to other compounds such as terpenoids and alkaloids, which are the major groups of medicinal compounds from plants.”

This research was strategically funded by the BBSRC, the EU ATHENA collaborative project, the Major State Basic Research Development Program (973 Program) of China, the John Innes Foundation, and the DBT-CREST Fellowship.

Source: Scientists produce beneficial natural compounds in tomato – with potential for industrial scale up