The Centre for Innovative Recycling and Circular Economy (CIRCLE) UK team will be led by Dr , Reader is Sustainable Biotechnology at the Swag直播 Institute of Biotechnology, alongside a team of international academics. Also part of the project are Professors and , and Drs , and Micaela Chacon.

CIRCLE aims to address the global challenge of anthropogenic waste by closing the loop and using it as a feedstock for the chemicals industry. Much of the waste produced by society is a rich source of carbon, a building block for many important chemicals and materials found in everyday products such as plastics, personal care products, and pharmaceuticals. CIRCLE will identify and employ novel biotechnological processes to break down this waste into its chemical components and avoid the need for virgin petrochemical feedstocks.

This project will bring together academic expertise from across the globe, including the US, Canada and South Korea.

The 2024 Global Centres awards focus on advancing bioeconomy research to solve global challenges, whether by increasing crop resilience, converting plant matter or other biomass into fuel, or paving the way for biofoundries to scale-up applications of biotechnology for societal benefit.  The programme supports holistic, multidisciplinary projects that bring together international teams and scientific disciplines, including education and social sciences, necessary to achieve use-inspired outcomes. All Global Centres will integrate public engagement and workforce development, paying close attention to impacts on communities.

鈥淎longside replacing fossil fuels, there is an urgent need to replace petrochemical industrial feedstocks across a wide range of sectors. This is a global challenge that requires global solutions and UKRI is delighted to be partnering in the NSF Global Centres 2024 programme to meet this need鈥�, said UKRI CEO, Professor Dame Ottoline Leyser. 鈥淭he announcement today will be at the forefront of real-world solutions, from improved recycling to new bioplastics, building a sustainable circular economy. The centres will create the global networks and skills needed to drive a thriving bioeconomy benefitting all.鈥�

These findings have the potential to accelerate the discovery of novel, more efficient cryoprotectants - and may also allow for the repurposing of molecules already known to slow or stop ice growth.

Professor Matthew Gibson, from Swag直播 Institute of Biotechnology at Swag直播, added: 鈥淢y team has spent more than a decade studying how ice-binding proteins, found in polar fish, can interact with ice crystals, and we鈥檝e been developing new molecules and materials that mimic their activity. This has been a slow process, but collaborating with Professor Sosso has revolutionized our approach. The results of the computer model were astonishing, identifying active molecules I never would have chosen, even with my years of expertise. This truly demonstrates the power of machine learning.鈥�

The full paper can be read .

Sugars play a crucial role in human health and disease, far beyond being just an energy source. Complex sugars called glycans coat all our cells and are essential for healthy function. However, these sugars are often hijacked by pathogens such as influenza, Covid-19, and cholera to infect us.

One big problem in treating and diagnosing diseases and infections is that the same glycan can bind to many different proteins, making it hard to understand exactly what鈥檚 happening in the body and has made it difficult to develop precise medical tests and treatments.

In a breakthrough, published in the journal , a collaboration of academic and industry experts in Europe, including from Swag直播 and the University of Leeds, have found a way to create unnatural sugars that could block the pathogens.

The finding offers a promising avenue to new drugs and could also open doors in diagnostics by 鈥榗apturing鈥� the pathogens or their toxins.

, a researcher from at Swag直播, said 鈥淒uring the Covid-19 pandemic, our team introduced the first lateral flow tests which used sugars instead of antibodies as the 鈥榬ecognition unit鈥�. But the limit is always how specific and selective these are due to the promiscuity of natural sugars. We can now integrate these fluoro-sugars into our biosensing platforms with the aim of having cheap, rapid, and thermally stable diagnostics suitable for low resource environments.鈥�

Professor Bruce Turnbull, a lead author of the paper from the School of Chemistry and Astbury Centre for Structural Molecular Biology at The University of Leeds, said 鈥淕lycans that are really important for our immune systems, and other biological processes that keep us healthy, are also exploited by viruses and toxins to get into our cells. Our work is allowing us to understand how proteins from humans and pathogens have different ways of interacting with the same glycan. This will help us make diagnostics and drugs that can distinguish between human and pathogen proteins.鈥�

The researchers used a combination of enzymes and chemical synthesis to edit the structure of 150 sugars by adding fluorine atoms. Fluorine is very small meaning that the sugars keep their same 3D shape, but the fluorines interfere with how proteins bind them.

, a researcher from Swag直播 Institute of Biotechnology at Swag直播, said 鈥淥ne of the key technologies used in this work is biocatalysis, which uses enzymes to produce the very complex and diverse sugars needed for the library. Biocatalysis dramatically speeds up the synthetic effort required and is a much more green and sustainable method for producing the fluorinated probes that are required.鈥�

They found that some of the sugars they prepared could be used to detect the cholera toxin 鈥� a harmful protein produced by bacteria 鈥� meaning they could be used in simple, low-cost tests, similar to lateral flow tests, widely used for pregnancy testing and during the COVID-19 pandemic.

Dr Kristian Hollie, who led production of the fluoro-sugar library at the University of Leeds, said: 鈥淲e used enzymes to rapidly assemble fluoro-sugar building blocks to make 150 different versions of a biologically important glycan. We were surprised to find how well natural enzymes work with these chemically modified sugars, which makes it a really effective strategy for discovering molecules that can bind selectively.鈥�

The study provides evidence that the artificial 鈥渇luoro-sugars鈥� can be used to fine-tune pathogen or biomarker recognition or even to discover new drugs. They also offer an alternative to antibodies in low-cost diagnostics, which do not require animal tests to discover and are heat stable.

The research team included researchers from eight different universities, including Swag直播, Imperial College London, Leeds, Warwick, Southampton, York, Bristol, and Ghent University in Belgium.

The breakthrough, published in the journal , could significantly improve accessibility of essential protein-based drugs in developing countries where cold storage infrastructure may be lacking, helping efforts to diagnose and treat more people with serious health conditions.

The researchers, from the Universities of Swag直播, Glasgow and Warwick, have designed a hydrogel 鈥� a material mostly made of water 鈥� that stabilises proteins, protecting its properties and functionality at temperatures as high as 50掳C.

The technology keeps proteins so stable that they can even be sent through the post with no loss of effectiveness, opening up new possibilities for more affordable, less energy-intensive methods of keeping patients and clinics supplied with vital treatments.

Protein therapeutics are used to treat a range of conditions, from cancer to diabetes and most recently to treat obesity and play a vital role in modern medicine and biotechnology. However, keeping them stable and safe for storage and transportation is a challenge. They must be kept cold to prevent any deterioration, using significant amounts of energy and limiting equitable distribution in developing countries.

The medicines also often include additives 鈥� called excipients 鈥� which must be safe for the drug and its recipients limiting material options.

The findings could have major implications for the diagnostics and pharmaceutical industries.

, is one of the paper鈥檚 corresponding authors. He said: 鈥淚n the early days of the Covid vaccine rollout, there was a lot of attention given in the news media to the challenges of transporting and storing the vaccines, and how medical staff had to race to put them in people鈥檚 arms quickly after thawing.  

鈥淭he technology we鈥檝e developed marks a significant advance in overcoming the challenges of the existing 鈥榗old chain鈥� which delivers therapeutic proteins to patients. The results of our tests have very encouraging results, going far beyond current hydrogel storage techniques鈥� abilities to withstand heat and vibration. That could help create much more robust delivery systems in the future, which require much less careful handling and temperature management.鈥�

The hydrogel is built from a material called a low molecular weight gelator (LMWG), which forms a three-dimensional network of long, stiff fibres. When proteins are added to the hydrogel, they become trapped in the spaces between the fibres, where they are unable to mix and aggregate 鈥� the process which limits or prevents their effectiveness as medicines.

The unique mechanical properties of the gel鈥檚 network of fibres, which are stiff but also brittle, ensures the easy release of a pure protein. When the protein-storing gel is stored in an ordinary syringe fitted with a special filter, pushing down on the plunger provides enough pressure to break the network of fibres, releasing the protein. The protein then passes cleanly through the filter and out the tip of the syringe alongside a buffer material, leaving the gel behind.

In the paper, the researchers show how the hydrogel works to store two valuable proteins: insulin, used to treat diabetes, and beta-galactosidase, an enzyme with numerous applications in biotechnology and life sciences.

Ordinarily, insulin must be kept cold and still, as heating or shaking can prevent it from being an effective treatment. The team tested the effectiveness of their hydrogel suspension for insulin by warming samples to 25掳C and rotating them at 600 revolutions per minute, a strain test far beyond any real-world scenario. Once the tests were complete, the team were able to recover the entire volume of insulin from the hydrogel, showing that it had been protected from its rough treatment.

The team then tested samples of beta-galactosidase in the hydrogel, which was stored at a temperature of 50掳C for seven days, a level of heat exceeding any realistic temperature for real-world transport. Once the enzyme was extracted from the hydrogel, the team found it retained 97% of its function compared against a fresh sample stored at normal temperature.

A third test saw the team put samples of proteins suspended in hydrogel into the post, where they spent two days in transit between locations. Once the sample arrived at its destination, the team鈥檚 analysis showed that the gels鈥� structures remained intact and the proteins had been entirely prevented from aggregating.

is the paper鈥檚 other corresponding author. He said: 鈥淒elivering and storing proteins intact is crucial for many areas of biotechnology, diagnostics and therapies. Recently, it has emerged that hydrogels can be used to prevent protein aggregation, which allows them to be kept at room temperature, or warmer. However, separating the hydrogel components from the protein or proving that they are safe to consume is not always easy. Our breakthrough eliminates this barrier and allows us to store and distribute proteins at room temperature, free from any additives, which is a really exciting prospect.鈥�

The team are now exploring commercial opportunities for this patent-pending technology as well as further demonstrating its applicability. 

Researchers from the University of East Anglia and Diamond Light Source Ltd also contributed to the research. The team鈥檚 paper, titled 鈥楳echanical release of homogenous proteins from supramolecular gels鈥�, is published in Nature.

The research was supported by funding from the European Union鈥檚 Horizon 2020 programme, the European Research Council, the Royal Society, the Engineering and Physical Sciences Research Council (EPSRC), the University of Glasgow and UK Research and Innovation (UKRI).

The centre has been awarded 拢1.2m through an International Centre to Centre grant from the Engineering and Physical Sciences Research Council, part of UK Research and Innovation. Led by Professor , Interim Director of the MIB, along with Professor and Dr , and in partnership with Professor David Baker from the Institute of Protein Design (IPD) at the University of Washington, ICED will employ the latest deep-learning protein design tools to accelerate the development of new biocatalysts for use across the chemical industry. The centre will deliver customised biocatalysts for sustainable production of a wide range of chemicals and biologics, including pharmaceuticals, agrochemicals, materials, commodity chemicals and advanced synthetic fuels.

Biocatalysis uses natural or engineered enzymes to speed up valuable chemical processes. This technology is now widely recognised as a key enabling technology for developing a greener and more efficient chemical industry. Although powerful, existing experimental methods for developing industrial biocatalysts are costly and time-consuming, and this restricts the potential impact of biocatalysis on many industrial processes. Furthermore, for many desirable chemical transformations there are no known enzymes that can serve as starting templates for experimental engineering. In ICED we will bring together leading computational and experimental teams from across academia and industry to bring about a step-change in the speed of biocatalyst development. The approaches developed will also allow the development of new families of enzymes with catalytic functions that are unknown in nature.

Professor David Baker, lead researcher from the Institute of Protein Design says; 鈥淎ccurately designing efficient enzymes with new catalytic functions is one of the grand challenges for the protein design field. We are thrilled to be working with Professor Green and his team in the MIB to address this crucial biotechnological challenge.鈥欌��

The design tools developed throughout the project will be readily available to specialists and non-specialists to support their own enzyme engineering and biocatalysis needs. As the centre develops, we expect to grow our partnerships with the wider academic and industrial sector to ensure that we can best serve the needs and ambitions of the global biocatalysis community.

With the chemical and pharmaceutical industries contributing 拢30.7bn to the UK economy alone, technologies like biocatalysis are poised to revolutionise how every day, essential products are made while also benefitting our health and our environment.

The bid was delivered by a coordination team, which includes and from the University and has secured 拢49.35m from the UKRI Infrastructure Fund to establish C-MASS - a national hub-and-spoke infrastructure designed to integrate and advance the country鈥檚 capability in mass spectrometry.

Mass spectrometry is a central analytical technique that quantifies and identifies molecules by measuring their mass and charge. It is used across science and medicine, for drug discovery, to screen all newborn babies for the presence of metabolic disorders, to monitor pollution and to tell us what compounds are in the tails of comets.

Researchers at Swag直播 develop and apply mass spectrometry in many of its research centres and institutes, including the , the , , , the , and the

C-MASS will enable rapid methodological advances, by developing consensus protocols to allow population level screening of health markers and accelerated data access and sharing. It will bring together cutting-edge instrumentation at a range of laboratories connected by a coordinating central hub that will manage a central metadata catalogue. Together, this will provide unparalleled signposting of data and will be a critical measurement science resource for the UK.

The bid for the funding has been developed over the last 10 years and has included input and support from more than 40 higher education institutes, 35 industrial partners and numerous research institutes.

Swag直播 is renowned for its expertise in mass spectrometry. J.J. Thomson, who was an alumnus of Swag直播, built the first mass spectrometer - originally called a parabola spectrograph - in 1912. Later, another alumnus, James Chadwick, commissioned the first commercial mass spectrometer, built by the Swag直播 firm Metropolitan Vickers, for use in the second world war to separate radioactive isotopes.

Now, many decades later, the University receives more funding in mass spectrometry than any other higher education institution in the UK and more mass spectrometers are made in the Swag直播 region than any other in Europe.

At the University, researchers across a range of disciplines including , , use mass spectrometry for wide range of world-leading research. Just some of those projects include: , improving the testing and diagnosis of womb cancer, improving our understanding of Huntington鈥檚 disease and rheumatic heart disease, diagnosing Parkinson鈥檚 disease and finding treatments for blindness.

The mass spectrometry laboratories at the University boast a range of industry-leading instrumentations, not just for staff and students, but also collaborating with many external companies. 

The awards celebrate outstanding women post-doctoral scientists, and forms part of the L鈥橭r茅al-UNESCO for Women in Science UK & Ireland Rising Talent Programme, which offers awards to promote, enhance and encourage the contribution of women pursuing their scientific research careers in the UK or Ireland.

Dr Swidah, a postdoctoral researcher at the Swag直播 Institute of Biotechnology, was one of five winners at the award at a ceremony at the House of Commons in London on Monday, 18 March.

Other winners were awarded in the categories of engineering, life sciences, mathematics and computing and physical science.

Reem said: 鈥淚 am honoured to announce that I have been awarded the prestigious L'Or茅al UNESCO Award for Women in Science in the category of Sustainable Development.  

鈥淭hese awards are vital for supporting and celebrating women in science, offering recognition and inspiration. It provides financial research support, fosters networking and collaboration among recipients, and contributes to reducing gender disparities in STEM fields. By highlighting the achievements of women scientists, the award inspires future generations and advocates for gender equality in science.

鈥淧rograms like L'Or茅al UNESCO  for women in science are critically important, providing vital recognition and support for women scientists while challenging prevailing stereotypes and biases.  Believe in yourself, defy stereotypes, continuously enhance your professional skills, and persist in pursuing your dreams. If opportunities don't come your way, create your own path. Seek mentors, embrace learning, take risks, step out of your comfort zone, and surround yourself with supportive peers. Remember, diversity in STEM drives progress and innovation.

鈥淭his award will enable me to balance motherhood and research while gaining the necessary support to make a meaningful impact in my field.鈥�

Reem received a 拢25,000 grant that is fully flexible and tenable at any UK or Irish university or research institute to support 12 months of research. Her work currently focuses on the genome minimization project (part of the Sc3.0 project initiative), focusing on genome minimization within the synthetic yeast strain (Sc2.0).

Reem was selected for the award for her drive and ambition to leverage her skills in synthetic biology to address global challenges and her work to harness the exceptional evolutionary abilities of synthetic yeast strains to develop innovative and cost-effective technologies to produce biofuels.

She believes that these advancements hold the potential to combat climate change and play a pivotal role in achieving the ambitious goal of Net Zero emissions by 2050, a key strategic objective of Swag直播.

She added: 鈥淭his award will enhance childcare support for my baby and will afford me the time and financial resources to develop my professional skills. I intend to engage in one-to-one career coaching programs and leadership training, which will help me unlock my full potential and excel in my role, which I currently cannot do.

鈥淭he grant will also enable me to attend international conferences, where I can engage with scientists and stay updated on global challenges and solutions and it will help me to enhance my research independence by using the grant to purchase small equipment and to conduct essential experiments to boost my research objectives.鈥�

The Women in Science National Rising Talents  is run in partnership between L鈥橭r茅al UK and Ireland, the UK National Commission for UNESCO and the Irish National Commission for UNESCO, with the support of the Royal Society.

Thierry Cheval, L'Or茅al UK and Ireland, Managing Director said: 鈥淎s a company founded by a scientist over 100 years ago, L鈥橭r茅al, together with UNESCO, is committed to driving gender equality in STEM and recognising the exceptional work of female scientists who are vitally contributing to solving the challenges of tomorrow.

鈥淐ongratulations to this year鈥檚 Fellows who are a true inspiration for generations to come.鈥�

Professor Anne Anderson, Chair of the UK National Commission for UNESCO's Board of Directors, added: 鈥淐ongratulations to the 2024 Rising Talents. As we stand at a pivotal moment in time for scientific advancement, UNESCO continues to highlight the importance of true gender equality in science, technology, engineering and mathematics (STEM) and the vital role women play in a more equitable scientific society.

鈥淭he United Kingdom National Commission for UNESCO is proud to support these young women in STEM from the UK & Ireland and celebrate their achievements as researchers paving the way for a brighter global future.鈥�

Carefully controlled inhalation of a specific type of 鈥� the world鈥檚 thinnest, super strong and super flexible material 鈥� has no short-term adverse effects on lung or cardiovascular function, the study shows.

The first controlled exposure clinical trial in people was carried out using thin, ultra-pure graphene oxide 鈥� a water-compatible form of the material.

Researchers say further work is needed to find out whether higher doses of this graphene oxide material or other forms of graphene would have a different effect.

The team is also keen to establish whether longer exposure to the material, which is thousands of times thinner than a human hair, would carry additional health risks.

There has been a surge of interest in developing graphene 鈥� at Swag直播 in 2004 and which has been hailed as a 鈥榳onder鈥� material. Possible applications include electronics, phone screens, clothing, paints and water purification.

Graphene is actively being explored around the world to assist with targeted therapeutics against cancer and other health conditions, and also in the form of implantable devices and sensors. Before medical use, however, all nanomaterials need to be tested for any potential adverse effects.

Researchers from the Universities of Edinburgh and Swag直播 recruited 14 volunteers to take part in the study under carefully controlled exposure and clinical monitoring conditions.

The volunteers breathed the material through a face mask for two hours while cycling in a purpose-designed mobile exposure chamber brought to Edinburgh from the National Public Health Institute in the Netherlands.

Effects on lung function, blood pressure, blood clotting and inflammation in the blood were measured 鈥� before the exposure and at two-hour intervals. A few weeks later, the volunteers were asked to return to the clinic for repeated controlled exposures to a different size of graphene oxide, or clean air for comparison.

There were no adverse effects on lung function, blood pressure or the majority of other biological parameters looked at.

Researchers noticed a slight suggestion that inhalation of the material may influence the way the blood clots, but they stress this effect was very small.

Dr Mark Miller, of the University of Edinburgh鈥檚 Centre for Cardiovascular Science, said: 鈥淣anomaterials such as graphene hold such great promise, but we must ensure they are manufactured in a way that is safe before they can be used more widely in our lives.

鈥淏eing able to explore the safety of this unique material in human volunteers is a huge step forward in our understanding of how graphene could affect the body. With careful design we can safely make the most of nanotechnology.鈥�

Professor Kostas Kostarelos, of Swag直播 and the Catalan Institute of Nanoscience and Nanotechnology (ICN2) in Barcelona, said: 鈥淭his is the first-ever controlled study involving healthy people to demonstrate that very pure forms of graphene oxide 鈥� of a specific size distribution and surface character 鈥� can be further developed in a way that would minimise the risk to human health.

鈥淚t has taken us more than 10 years to develop the knowledge to carry out this research, from a materials and biological science point of view, but also from the clinical capacity to carry out such controlled studies safely by assembling some of the world鈥檚 leading experts in this field.鈥�

Professor Bryan Williams, Chief Scientific and Medical Officer at the British Heart Foundation, said: 鈥淭he discovery that this type of graphene can be developed safely, with minimal short term side effects, could open the door to the development of new devices, treatment innovations and monitoring techniques.

鈥淲e look forward to seeing larger studies over a longer timeframe to better understand how we can safely use nanomaterials like graphene to make leaps in delivering lifesaving drugs to patients.鈥�

The study is published in the journal Nature Nanotechnology: .It was funded by the British Heart Foundation and the UKRI EPSRC.

Swag直播 is the recipient of five awards, including:

• , Senior Lecturer in Chemical Biology and Biological Chemistry of the , and , Professor of Polymer Science at the Henry Royce Institute, who are a Co-Investigators on a Mission Hub led by the University of Portsmouth. The mission Hub is looking into how engineering biology can tackle plastic waste.
• , Professor of Geomicrobiology, from the Department of Earth and Environmental Sciences, is involved in a Mission Hub led by the University of Kent, and also leads a Mission Award, both of which will be looking at ways to use engineering biology to process metals, including for bioremediation and for metal recovery from industrial waste streams.
• , , and of the Swag直播 Institute of Biotechnology, received a Mission Award for a project that will engineer biological systems to enable economical production of functionalised proteins including biopharmaceuticals and industrial biocatalysts.
• , Chair in Evolutionary Biology, from the Division of Evolution, Infection and Genomics, and Professor Patrick Cai of the Swag直播 Institute of Biotechnology, are looking into engineering phages with intrinsic biocontainment to develop new treatments against drug-resistant bacterial infections.

The hubs are funded for five years through UKRI and the Biotechnology and Biological Sciences Research Council (BBSRC) and are a collaboration between academic institutions and industrial partners. The Mission Award Projects are funded for two years. These projects will expand upon our current knowledge of engineering biology and capitalise on emerging opportunities.

Announcing the funding the Science, Research and Innovation Minister, Andrew Griffith, said: 鈥淓ngineering biology has the power to transform our health and environment, from developing life-saving medicines to protecting our environment and food supply and beyond.

鈥淥ur latest 拢100m investment through the UKRI Technology Missions Fund will unlock projects as diverse as developing vaccines鈥reventing food waste through disease resistant crops, reducing plastic pollution, and even driving efforts to treat snakebites.

鈥淲ith new Hubs and Mission Awards spread across the country, from Edinburgh to Portsmouth, we are supporting ambitious researchers and innovators around the UK in pioneering groundbreaking new solutions which can transform how we live our lives, while growing our economy.鈥�

Engineering biology has the potential to tackle a diverse range of global challenges, driving economic growth in the UK and around the world, as well as increase national security, resilience and preparedness.  Swag直播 has a broad range of expertise in engineering biology across its three Faculties and is also home to the international centre of excellence, the Swag直播 Institute of Biotechnology.

In Dr Stefan Hoffmann, lead author on the paper, and have found that by adding an estradiol-controlled destabilising domain degron (ERdd) to the genetic makeup of baker's yeast (Saccharomyces cerevisiae), they can control survival of the organism.

Destabilising domain (DD) degrons are an element of a protein that allow for degradation, unless a particular ligand 鈥� a small molecule that binds with the DD degron 鈥� is present to stabilise it. The researchers engineered the yeast to degrade proteins essential for life unless estradiol, a type of oestrogen, was present. Without estradiol, the yeast would die.

This new genetic containment technique differs from previous techniques in that it directly targets essential proteins. It has no detrimental effects on organism function, even when compared with the wild-type organism and it remains an active part of the genome, even after 100 generations.

To achieve this, the researchers tagged 775 essential genes with the ERdd tag and screened the resulting organisms for estradiol-dependent growth. Through this screening, they identified three genes, SPC110, DIS3, and RRP46 as suitable targets. The modified yeast grew well in the presence of estradiol and failed to thrive in its absence.

Professor Patrick Cai, Chair in Synthetic Genomics, said: 鈥�Safety mechanisms are instrumental for the deployment of emerging technologies such as engineering biology. The development of biocontainment systems will effectively minimize the risk associated with the emerging technologies, and to protect both the researchers and the wider community. It also provides a novel solution to combat intellectual espionage to safeguard our ever-growing bio-economy. This work is a great example of the responsible innovation of MIB research.鈥�

Engineering biology is a relatively new, but expanding field of science that allows industry to use microorganisms, such as yeasts and bacteria, to produce value-added chemicals cheaply and efficiently. However, as microorganisms are often genetically engineered to increase efficacy, it becomes a problem if the organisms escape into the natural environment.

To ensure modified organisms do not find their way out of an laboratory setting, the NIH sets strict escape rate thresholds. Currently, most genetic safeguards rely on one of two methodologies to keep within the guidelines: either by engineering in an auxotrophy, whereby the organism relies on a specific metabolite to be present in its environment to survive, or a 鈥渟uicide鈥� gene, where the organism itself produces a toxin that kills it if certain conditions are not met.  

While these methods are generally genetically stable and effective enough to meet the NIH guidelines, they do have caveats to their efficacy. In the case of relying on a metabolite to sustain the organism, this metabolite may also be found in the wild and could not ensure the organism does not survive if it escapes. For 鈥渟uicide鈥� genes, as this is a direct threat to the organism, over generations the gene can selectively mutate and become inactive rendering it an ineffective control.

The new biocontainment method described by Hoffmann and Cai could be used in conjunction with the existing methods to bolster their effectiveness and deliver an even more robust escape frequency. Even if used as the sole biocontainment method, it provides an escape frequency of <2x10^-10 which far exceeds the NIH guideline of an escape rate of less than 10^-8.  

Today, the and The announced the nine recipients of the 2024 Blavatnik Awards for Young Scientists in the UK, including three Laureates and six finalists.

and are named among the three Laureates, who will each receive 拢100,000 in recognition of their work in Chemical Sciences and Physical Sciences & Engineering, respectively.

Now in its seventh year, the awards are the largest unrestricted prizes available to UK scientists aged 42 or younger. The awards recognise research that is transforming medicine, technology and our understanding of the world.

This year鈥檚 Laureates were selected by an independent jury of expert scientists from across the UK.

Professor Anthony Green, a Lecturer in Organic Chemistry from Swag直播, has been named the Chemical Sciences Laureate for his discoveries in designing and engineering new enzymes, with valuable catalytic functions previously unknown in nature that address societal needs. Recent examples include the development of biocatalysts to produce COVID-19 therapies to break down plastics, and to use visible light to drive chemical reactions. 

Rahul Nair, Professor of Materials Physics at Swag直播, was named Laureate in Physical Sciences & Engineering for developing novel membranes based on two-dimensional (2D) materials that will enable energy-efficient separation and filtration technologies. Using graphene and other 2D materials, his research aims to study the transport of water, organic molecules, and ions at the nanoscale, exploring its potential applications to address societal challenges, including water filtration and other separation technologies.

Internationally recognised by the scientific community, the Blavatnik Awards for Young Scientists are instrumental in expanding the engagement and recognition of young scientists and provide the support and encouragement needed to drive scientific innovation for the next generation.

, Founder and Chairman of Access Industries and Head of the Blavatnik Family Foundation, said: 鈥淧roviding recognition and funding early in a scientist鈥檚 career can make the difference between discoveries that remain in the lab and those that make transformative scientific breakthroughs.

鈥淲e are proud that the Awards have promoted both UK science and the careers of many brilliant young scientists and we look forward to their additional discoveries in the years ahead.鈥�

, President and CEO of The New York Academy of Sciences and Chair of the Awards鈥� Scientific Advisory Council, added: 鈥淔rom studying cancer to identifying water in far-off planets, to laying the groundwork for futuristic quantum communications systems, to making enzymes never seen before in a lab or in nature, this year鈥檚 Laureates and Finalists are pushing the boundaries of science and working to make the world a better place. Thank you to this year鈥檚 jury for sharing their time and expertise in selecting these daring and bold scientists as the winning Laureates and Finalists of the 2024 Blavatnik Awards for Young Scientists in the UK.鈥�

The 2024 Blavatnik Awards in the UK Laureates and Finalists will be honoured at a black-tie gala dinner and award ceremony at Banqueting House in Whitehall, London, on 27 February 2024.

With support from the , the UK鈥檚 national centre for research and innovation for advanced materials, the lab gives researchers and industry access to the complete fabrication pipeline from cell culturing to product evaluation.

Funded by a 拢200,000 grant from the UK Space Agency and assisted by the European Space Agency, a University of Swag直播 team are currently investigating how to optimise the bioprinting process for conditions experienced in space, such as lack of gravity.

Using the unique capabilities of the BTP, researchers are also collaborating with clinicians and cell biologists to develop 3D models of human cartilage and bone.

Mr Green, who before entering Parliament spent almost two decades working as an engineer in the mass spectrometry industry, began his trip at the - the most advanced nuclear research capability in UK academia - where he was briefed on current projects by Professor Adrian Bull MBE, Chair in Nuclear Energy and Society. 

The Bolton West MP鈥檚 final destination on the visit, organised by the University鈥檚 policy engagement unit , was the Justice Hub to join a health-themed roundtable discussion with senior academics including Dr Philip Drake, Dr Jennifer Voorhees and Dr Jonathan Hammond.   

Professor Richard Jones, Vice President for Civic Engagement and Innovation at Swag直播, said: 鈥淚t was a pleasure to welcome Chris and give him an insight into some of the pioneering work we do in partnership with businesses right across Greater Swag直播.

鈥淪wag直播's cutting-edge research in making a real difference in tackling pressing policy challenges.  That's why it is important for influencers of policy, including MPs across Greater Swag直播, to see at first-hand the work being done and to take that evidence back with them to Westminster. 

鈥淭his was a particularly timely visit as the Chancellor announced a new investment zone for Greater Swag直播 in the recent Autumn Statement which will give further impetus to the work we do on innovation, advanced materials and manufacturing with our partners in the city-region."

Chris Green MP said: 鈥淚t was a fascinating morning. Swag直播 has a thoroughly merited global reputation for research excellence across a vast swathe of subject areas, not least in technology, innovation and health.

鈥淚 was deeply impressed by all I saw and heard, particularly in the Bioprinting Technology Platform where the remarkable work going on places Greater Swag直播 firmly at the forefront of the medical engineering revolution.

鈥淚 look forward to following the many exciting research projects happening across the University, with lots more in development.鈥�          

MOOCs were set up in the mid-2000s to offer learning opportunities to distance learners. Since their inception they have brought education to thousands around the world, usually for free or at a low cost compared with traditional degrees. They have been credited with helping democratise higher education (HE) especially for those in developing nations by offering them a way to receive education from universities around the world, in a way and at a time that suits them.

The industrial biotechnology MOOC was designed and coordinated by Lesley-Ann Miller and Dr. Nicholas Weise from the Swag直播 Institute of Biotechnology, drawing together expertise from the University, and beyond, through a selection of contributors. The modules, which are all freely available worldwide to anyone with an internet connection, covers topics such as enzyme catalysis, synthetic biology, biochemical engineering, pharmaceutical synthesis, biomaterials, bioenergy and glycobiotechnology.  

The course exemplifies how industrial biotechnology can be used by society to meet global net zero goals and create more sustainable routes to manufacture of everyday products, as well as specialist chemicals used by industry. Since the Industrial Revolution, society has relied upon fossil fuels to provide the raw materials for many everyday products including pharmaceuticals, food and drink, materials, plastics, and personal care products.

With government targets drawing closer, industry must find new ways to manufacture these products without relying on finite resources. Industrial biotechnology offers a way for industry to adapt and change to meet these targets while still being able to produce high-quality and high-yielding products with a smaller impact on the environment.

Course instructors, Prof. Nicholas Turner, Dr. Nicholas Weise and Prof. Nigel Scruton, are delighted that the course has been used by hundreds of thousands as a way to access knowledge of sustainable bio-inspired technologies. The course is designed to help those looking to enter the field of biotechnology, upskill or even retrain to help solve technological challenges in their own areas. The course has received an average rating of 4.7/5.0 with learner stories such as:

Open dissemination of expertise from the University that can be used to solve global challenges is an important part of the research impact and social responsibility agenda for the university. The course has already received a recognition for its innovative practices in teaching and learning from the LearnSci Teaching Innovation Awards, a Teaching Excellence Award from the Institute of Teaching & Learning as well as being highly commended at the Making A Difference Awards for outstanding teaching innovation in social responsibility. 

Researchers in the Swag直播 Institute of Biotechnology (MIB) at Swag直播 have created the tRNA Neochromosome 鈥� a chromosome that is new to nature.

It forms part of a wider project (Sc2.0) that has now successfully synthesised all 16 native chromosomes in Saccharomyces cerevisiae, common baker鈥檚 yeast, and aims to combine them to form a fully synthetic cell.

The international team has already combined six and a half synthetic chromosomes in a functional cell. It is the first time scientists have written a eukaryotic genome from scratch.

Yeasts are a common workhorse of industrial biotechnological processes as they allow valuable chemicals to be produced more efficiently, economically, and sustainably. They are often used in the production of biofuels, pharmaceuticals, flavours and fragrances, as well as in the more well-known fermentation processes of bread-making and beer-brewing.

Being able to re-write a yeast genome from scratch could create a strain that is stronger, works faster, is more tolerant to harsh conditions and has a higher yield.

The process also sheds light on the traditionally problematic genome fundamentals, such as how genomes are organised and evolved.

The findings of both projects, published as two research articles of the prestigious journals Cell and Cell Genomics respectively, are a culmination of 10 years of research from an international consortium of scientists led by Professor Patrick Cai and Swag直播, and mark a new chapter in engineering biology.

Swag直播鈥檚 research also features on the front covers of both journals.

Prof Cai, Chair in Synthetic Genomics at Swag直播 who is the international coordinator of Sc2.0 project, said: 鈥淭his is an exciting milestone when it comes to engineering biology. While we have been able to edit genes for some time, we have never before been able to write a eukaryote genome from scratch. This work is fundamental to our understanding of the building blocks of life and has the potential to revolutionise synthetic biology which is fitting as Swag直播 is the home of the Industrial Revolution. Now, we鈥檙e at the forefront of the biotechnological revolution too.

鈥淲hat鈥檚 remarkable about this project is the sheer scale of collaboration and the interdisciplinarity involved in bringing it to fruition. We鈥檝e brought together not only our experts here in the MIB, but also experts from across the world in fields ranging from biology and genomics to computer science and bioengineering.

Dr Daniel Schindler, one of the two lead authors and group leader at the Max Planck Institute for Terrestrial Microbiology and the Center for Synthetic Microbiology (SYNMIKRO) in Marburg, added: "The international Sc2.0 is a fascinating, highly interdisciplinary project. It combines basic research to expand our understanding of genome fundamentals, but also paves the way for future applications in biotechnology and drives technology developments.

鈥淭he international and inclusive nature of the project has unleashed the science and seeded future collaborations and friendships. The Swag直播 Institute of Biotechnology, with its excellent research environment and open space, has always facilitated this."

The tRNA neochromosome is used to house and organise all 275 nuclear tRNA genes from the yeast and will eventually be added to the fully synthetic yeast where the tRNA genes have been removed from the other synthesised chromosomes. 

Unlike the other synthetic chromosomes of the Sc2.0 project, the tRNA neochromosome has no native counterpart in the yeast genome.

It was designed using AI assisted, computer-assisted design (CAD), manufactured with state-of-the-art roboticized foundries, and completed by comprehensive genome-wide metrology to ensure the high fitness of the synthetic cells.

Next, the researchers will work together to bring all the individual synthetic chromosomes together into a fully synthetic genome. The final Sc2.0 strain will not only be the world鈥檚 first synthetic eukaryote, but also the first one to be built by the international community.

鈥淭he potential benefits of this research are universal 鈥� the limiting factor isn鈥檛 the technology, it鈥檚 our imagination鈥�, says Prof Cai.

The centre, led Dr Mauricio A 脕lvarez, will train the next generation of AI researchers to develop AI methods designed to accelerate new scientific discoveries 鈥� specifically in the fields of astronomy, engineering biology and material science.

The University will be working in partnership with The University of Cambridge, and is one of 12 Centres for Doctoral Training (CDTs) in Artificial Intelligence (AI) based at 16 universities, announced by UK Research and Innovation (UKRI) today (31 October).

The investment by UKRI aims to ensure that the UK continues to have the skills needed to seize the potential of the AI era, and to nurture the British tech talent that will push the AI revolution forwards. 

拢117 million in total has been awarded to the 12 CDTs and builds on the previous UKRI investment of 拢100 million in 2018.

Doctoral students at Swag直播 will be provided with a foundation in Machine Learning and AI and an in-depth understanding of the implications of its application to solve real-world problems.

The programme will also cover the areas of responsible AI and equality, diversity and inclusion.

Dr Mauricio A 脕lvarez, Senior Lecturer in Machine Learning at Swag直播, said: "We are delighted to be awarded funding for this new AI CDT. Swag直播 is investing heavily in AI research and translation, and the CDT will complement other significant efforts in research through our AI Fundamentals Centre at the University and innovation via the Turing Innovation Catalyst. Our partnership with Cambridge will also enable us to educate experts capable of generalising and translating nationally to stimulate the development and adoption of AI technology in high-potential, lower AI-maturity sectors.

鈥淢odern science depends on a variety of complex systems, both in terms of the facilities that we use and the processes that we model. AI has the potential to help us understand these systems better, as well as to make them more efficient.

鈥�The AI methods we will develop will apply to a wide range of challenges in complex systems, from transport systems to sports teams. We are partnering with a diverse pool of industry collaborators to address these challenges jointly."

Dr Julia Handl, Professor in Decision Sciences at Swag直播, said: 鈥淭his CDT is a fantastic opportunity to bring together researchers from a wide spectrum of disciplines, from across all three of Swag直播鈥檚 Faculties, to ensure we can develop innovative solutions that are appropriate to the complexity and uncertainty of real-world systems. The involvement of the Faculty of Humanities is crucial in ensuring such systems are effective and inclusive in supporting human decision makers, and in delivering the centre鈥檚 cross-cutting theme of increasing business productivity, supported by collaboration with the Productivity Institute, the Masood Enterprise Centre and a range of industry partners.鈥�

UKRI Chief Executive, Professor Dame Ottoline Leyser, said: 鈥淭he UK is in a strong position to harness the power of AI to transform many aspects of our lives for the better. Crucial to this endeavour is nurturing the talented people and teams we need to apply AI to a broad spectrum of challenges, from healthy aging to sustainable agriculture, ensuring its responsible and trustworthy adoption. UKRI is investing 拢117 million in Centres for Doctoral Training to develop the talented researchers and innovators we need for success.鈥�

Dr Kedar Pandya, Executive Director, Cross-Council Programmes at UKRI, said: 鈥淭his 拢117 million investment, will involve multiple business and institutional partners for the Centres of Doctoral Training. These include well-known brands such as IBM, Astra Zeneca, and Google, as well as small to medium sized enterprises that are innovating in the AI field. A further 拢110 million has been leveraged from all partners in the form of cash or in-kind contributions such as use of facilities, resources or expertise.鈥�

The first cohort of UKRI AI CDT students will start in the 2024/2025 academic year, recruitment for which will begin shortly.

IBIC is a collaborative initiative, led by Swag直播, aimed at harnessing the region's scientific and research expertise to accelerate knowledge exchange, impact, and innovation, while fostering a more productive, research-intensive economy and promoting sustainability.

Industrial Biotechnology is a multi-disciplinary field that utilises biological resources for everyday product development, including food, fuels, and medicines. It is poised for significant growth with a market potential exceeding 拢34 billion in the UK alone. The confluence of consumer demand, carbon emission targets, and technological advancements requires new approaches to manufacturing, especially using methods that are divested of petrochemical feedstocks, and industrial biotechnology offers the solutions.

Together with the Universities of Liverpool, Swag直播 Metropolitan, Bolton and Salford, Swag直播 will lead a consortium of academia and industry and create a cohesive ecosystem for IB innovation. The new 拢5million EPSRC Place-Based Impact Acceleration Account (PBIAA) builds on an existing critical mass of IB expertise in the Northwest including the Swag直播 Institute of Biotechnology鈥檚 pioneering work (recognised by a Queen鈥檚 Anniversary Prize in 2019), major healthcare and biomanufacturing companies like AstraZeneca, Teva, Croda, and Unilever. As well as thriving SME innovation zones, including Daresbury, Liverpool Knowledge Quarter, and Alderley Park, the UK's largest life science campus. 

Professor Miles Padgett, Interim Executive Chair at EPSRC, said:

鈥淚鈥檓 pleased to announce our first ten Place Based Impact Acceleration Accounts which will play a unique role in enhancing the capabilities of innovation clusters across the UK. A key priority for UKRI is to strengthen clusters and partnerships in collaboration with civic bodies and businesses, thereby driving regional economic growth.鈥�

Science Minister, George Freeman, said: 鈥淏iotechnology delivers for our health, planet, prosperity and beyond and by targeting the North-West through our 拢41m place-based investment, we can build on the region鈥檚 thriving innovation cluster and better integrate the UK鈥檚 renowned research activity.

鈥淥ur investment will also create hundreds of new jobs, projects and businesses that will in turn drive investment to the region to grow the local and wider UK economy.鈥�

Professor Claire Eyers, Associate Pro Vice Chancellor for Research and Impact in the Faculty of Health and Life Sciences at the University of Liverpool, said: 鈥淭he University of Liverpool is one of the UK鈥檚 leading research-intensive higher education institutions. We pride ourselves in having a long history of working with a variety of organisations and this collaboration allows for the further application of our world-class research to solve real-world challenges.

We very much look forward to working with our regional partners to combine knowledge and expertise and create meaningful and lasting impact for a thriving north-west innovation ecosystem.鈥�

Dr Damian Kelly, Vice President 鈥� Innovation & Technology Development at Croda is fully supportive of the initiative: 鈥淎t Croda we are committed to be climate, land and people positive by 2030. We work to identify functional materials that can be manufactured from widely available, non-fossil materials while also developing low emission processing.  We are looking forward to being an active member of the IBIC ecosystem and engaging with the collaborative mechanisms.鈥�

The launch of IBIC is expected to stimulate significant investments, create numerous job opportunities, foster collaborative projects, and drive economic growth across the region. Building upon the region鈥檚 current credentials of a workforce of 25,000 people and a more than 拢6 billion turnover each year, the cluster is predicted to directly stimulate 拢2.5M cash and 拢4M in-kind co-investment, establish 150 collaborative projects, train 200+ students, create up to 100 green jobs, and establish 20+ new commercial ventures which could attract a further 拢10M in investment. This would see the cluster delivering a minimum 3:1 economic return on public investment over the medium term, with long-term plans to become an independent, business-led cluster of excellence.

For more information about IBIC and its initiatives, contact Professor Miller via email: aline.miller@manchester.ac.uk.

The research, funded by the Biotechnology and Biological Sciences Research Council鈥檚 (BBSRC) strategic Longer and Larger (sLoLa) grants programme, takes the first major step towards understanding complex microbial communities and will support the move towards a more sustainable and Net Zero future.

The University is one of four institutions to receive a share of 拢18 million from the BBSRC to support adventurous research aimed at tackling fundamental questions in bioscience.

The project, worth 拢5.4 million, builds on the work of the Swag直播 Microbiome Network - a network that brings together the leading microbiome science expertise from across the University to deliver a step-change in understanding microbial communities, regardless of habitat.

Lead researcher, Professor Sophie Nixon, BBSRC David Phillips and Dame Kathleen Ollerenshaw Fellow at Swag直播, said: 鈥淢icrobial communities, often called microbiomes, are found in almost every habitable environment on the planet. They exert a significant influence on each of these environments, whether that be the soil we grow our food, in the guts of animals, or even in extreme environments like geothermal springs 鈥� our target environment for this project. However, microbiomes are inherently complex and challenging to study, and their 鈥榬ules of life鈥� remain obscure.

鈥淩ecent technological advances have allowed researchers to study the interactions between members of microbiomes for the first time. Yet, we have barely scratched the surface of resolving how these interactions affect the structure, function, and stability of the community as a whole.   

Over five years, the researchers from Swag直播 and the Earlham Institute will concentrate on low-diversity communities inhabiting geothermal springs, using a powerful combination of biochemical, 鈥榦mics, and synthetic biology approaches to uncover the rules that govern microbial life in communities.

Using a tractable model system, the team aim to engineer the microbial community both as a learning tool to test emerging hypotheses, such as the ways in which microbes depend on or hinder one another, and as a testbed for future biotechnological development.

Ultimately, the findings will facilitate the engineering of bespoke microbial communities to be used for a plethora of important applications, including new ways to bio-convert CO2 emissions into socio-economically beneficial compounds, contributing toward a more sustainable and Net Zero future. 

Professor Guy Poppy, Interim Executive Chair at BBSRC, said: 鈥淭he latest investment by BBSRC鈥檚 sLoLa award programme represents a pivotal step in advancing frontier bioscience research.

鈥淭hese four world-class teams are poised to unravel the fundamental rules of life, employing interdisciplinary approaches to tackle bold challenges at the forefront of bioscience.

鈥淏y fostering collaboration and innovation, we aim to catalyse ground-breaking discoveries with far-reaching implications for agriculture, health, biotechnology, the green economy and beyond.鈥�

Swag直播鈥檚 research team includes seven researchers from the Faculty of Science and Engineering (five of which are based in the flagship Swag直播 Institute of Biotechnology), two from the Faculty of Biology, Medicine and Health, and one from the Earlham Institute - a life science research institute based in Norwich.

Bioprinting involves using specialised 3D printers to print living cells creating new skin, bone, tissue or organs for transplantation.

The technique has the potential to revolutionise medicine, and specifically in the realm of space travel, bioprinting could have a significant impact.

Astronauts on extended space missions have an increased health risk due to the absence of gravity and exposure to radiation. This makes them susceptible to diseases such as osteoporosis caused by loss of bone density and can cause injuries, such as fractures, which currently can鈥檛 be treated in space.

By harnessing bioprinting capabilities in space, researchers aim to protect the health of space explorers.

Currently, bioprinting machines rely on Earth鈥檚 gravity to function effectively. The new research by Swag直播, funded by a 拢200,000 grant from the UK Space Agency and supported by the European Space Agency, seeks to understand how to optimise the bioprinting process for conditions experienced in space, such as lack of gravity.

Dr Marco Domingos, Senior Lecturer in Mechanical and Aeronautical Engineering at Swag直播, said: 鈥淭his project marks a significant leap forward in bioprinting technology and by addressing the challenges posed by microgravity, we are paving the way for remarkable advancements in medicine and space exploration.鈥�

Libby Moxon, Exploration Science Officer for Lunar and Microgravity, added: 鈥淪wag直播鈥檚 pioneering project investigating a novel approach for bioprinting in space will help strengthen the UK鈥檚 leadership in the areas of fluid mechanics, soft matter physics and biomaterials, and could help protect the health of astronauts exploring space around the Earth, Moon and beyond.

鈥淲e鈥檙e backing technology and capabilities that support ambitious space exploration missions to benefit the global space community, and we look forward to following this bioprinting research as it evolves.鈥�

Eventually, the team, including Dr Domingos, Prof Anne Juel and Dr Igor Chernyavsky, will take their findings to a bioprinting station being developed on board the International Space Station, which will allow researchers to print models in space and study the effects of radiation and microgravity.

Dr Domingos said: 鈥淭he first challenge is figuring out how to print anything where there is no gravity. There are few facilities in the UK that are suitable to study the bioprinting process within an environment that matches that of space 鈥� they are either too small, or the time in which microgravity conditions are applies are too short. Hence, it is important to print in space to advance our knowledge in this field.

鈥淏y combining the principles of physics with bioprinting at Swag直播, we hope to come up with a solution before taking it to the International Space Station for testing.鈥�

The project will take place over two years at the Bioprinting Technology Platform based at the Henry Royce Institute on Swag直播鈥檚 campus.

It hopes to develop beyond the challenge of microgravity to address further challenges of preserving, transporting and processing cells in space.

Therapeutic oligonucleotides are an emerging class of drug molecules that have the potential to treat a wide range of diseases.

The finding, by Swag直播, will facilitate large-scale production of oligonucleotides to ensure the widest possible access of these drugs for patients.

Oligonucleotides are short sequences of DNA that can modulate or control gene expression. In this way, they have the potential to address the underlying causes of various diseases such as heart disease, cancer, and muscular dystrophy.

Over recent years, there has been an increasing number of approved oligonucleotide-based therapies, but widespread use of the drug has been limited in part because of difficulties in its manufacturing process.

Current methods rely on chemical synthesis that requires large amounts of solvent, generates substantial waste, and delivers final products with low yield and modest purity. Reactions are performed on solid supports or columns, which limits scalability, making them suitable only for producing oligonucleotides in small batches.

The new research, published in the journal , presents a sustainable and scalable approach to oligonucleotide production, addressing the challenges associated with current methods.

The findings could have major implications for the pharmaceutical industry.

Sarah Lovelock, Senior Lecturer at the Swag直播 Institute of Biotechnology at Swag直播, said: 鈥淭herapeutic oligonucleotides are an exciting new drug modality with huge potential to treat a wide range of diseases, including genetic disorders and viral infections.

鈥淢any pharmaceutical companies have therapeutic oligonucleotide candidates in their pipelines, including those for common diseases. The development of more scalable and sustainable approaches to oligonucleotide production will be key to ensuring the widest possible access to this powerful class of therapeutics.鈥�

In nature, DNA can be copied or amplified using enzymes called polymerases. The new approach uses these polymerases to amplify a catalytic DNA template to make a high volume of therapeutic oligonucleotides in a single step. This contrasts the iterative rounds of chain extension, capping, oxidation and deprotection associated with established methods.

Researchers at the University of Swag直播 are now working in a collaborative partnership with technology innovation catalyst CPI, AstraZeneca, and Novartis to scale up the approach presented within this research. 

The Enzyme Discovery team won the Chemistry Biology Interface Horizon Prize: Rita and John Cornforth Award, while the Molecular Ratcheteers team won the Organic Chemistry Horizon Prize: Perkin Prize in Physical Organic Chemistry. 

The Enzyme Discovery team was recognised for its work investigating enzymes to combat antimicrobial resistance in the developing world. 

The team, based at the and the at Swag直播, with collaborators from GlaxoSmithKline, won the accolade for successfully discovering new enzymes for sustainable synthesis.

Their findings could lead to more affordable medicines, antibiotics that are more resistant to antimicrobial resistance, and even treat previously untreated diseases.  

Professor Jason Micklefield from the Swag直播 Institute of Biotechnology and the Department of Chemistry at Swag直播, said: 鈥淥ur team is acutely aware of the importance of finding more sustainable and efficient routes to new and improved antimicrobials and other important therapeutic agents that are urgently required to combat antimicrobial resistance, treat diseases and tackle future pandemics.  

鈥淥ur research has allowed us to discover and engineer enzymes and pathways for sustainable synthesis, and we look forward to the future applications of our work in providing more parts of the world with increased access to essential medicines and more sustainable routes to commonly used products.鈥�  

If adopted in industry, the Enzyme Discovery team鈥檚 work could lead to more affordable products, including medicines, which could be made more widely available to help combat antimicrobial resistance and other neglected diseases in the developing world. Their work also has the potential to help reduce other problems such as chemical waste. 

The Molecular Ratcheteers team was recognised for its work in nanotechnology, advancing the building blocks for everything from medicine delivery to information processing.

Based at the University of Swag直播, with support from the University of Maine, the University of Luxembourg and East China Normal University, the Molecular Ratcheteers won the accolade for inventing engineering concepts that will help unlock the potential of the nanoworld.

The work leads to a variety of real-life applications like the creation of new nanomachines such as molecular motors, pumps and switches, that could make improvements in everything from the delivery of medicines to information processing. 

The group 鈥� which brought together minds with specialities in areas such as the physics of information and molecular biology 鈥� join a prestigious list of past winners in the RSC鈥檚 prize portfolio, 60 of whom have gone on to win Nobel Prizes for their work, including 2022 laureate Carolyn Bertozzi and 2019 laureate, John B Goodenough. 

Professor Dave Leigh from the Molecular Ratcheteers team at Swag直播, said: 鈥淚t鈥檚 been fantastic to be part of such a talented team on the Molecular Ratcheteers project, and we鈥檙e proud to have developed concepts that could truly drive forward engineering in the nanoworld.鈥� 

Miniaturisation has driven advances in technology through the ages. Early computers filled entire rooms and consumed vast amounts of energy yet had far less computing power than the tiny energy-frugal chips in today鈥檚 smartphones.

Making machinery smaller reduces power requirements, curtails the amounts of materials needed, cuts waste, facilitates recycling and produces faster operating systems. In doing so it advances technological progress while addressing the environmental and sustainability needs of society. 

Both research teams will also receive a trophy and a professionally produced video to celebrate the work. 

Dr Helen Pain, Chief Executive of the Royal Society of Chemistry, said: 鈥淭he Horizon Prizes recognise brilliant teams and collaborations who are opening new directions and possibilities in their field, by combining their diversity of thought, experience and skills, to deliver scientific developments for the benefit of all of us.  

鈥淭he work of the Enzyme Discovery team is a fantastic example of why we celebrate great science; not only because of how they have expanded our understanding of the world around us, but also because of the incredible contribution they make to society as a whole. We are very proud to recognise their work.鈥� 

The Royal Society of Chemistry鈥檚 prizes have recognised excellence in the chemical sciences for more than 150 years. In 2019, the organisation announced the biggest overhaul of this portfolio in its history, designed to better reflect modern scientific work and culture. 

The Horizon Prizes celebrate the most exciting, contemporary chemical science at the cutting edge of research and innovation.  

For more information about the Royal Society of Chemistry鈥檚 prizes portfolio, visit .

Building infrastructure in space is currently prohibitively expensive and difficult to achieve. Future space construction will need to rely on simple materials that are easily available to astronauts, StarCrete offers one possible solution. 

The scientists behind the invention used simulated Martian soil mixed with potato starch and a pinch of salt to create the material that is twice as strong as ordinary concrete and is perfectly suited for construction work in extra-terrestrial environments.

In an article published in the journal , the research team demonstrated that ordinary potato starch can act as a binder when mixed with simulated Mars dust to produce a concrete-like material. When tested, StarCrete had a compressive strength of 72 Megapascals (MPa), which is over twice as strong as the 32 MPa seen in ordinary concrete. Starcrete made from moon dust was even stronger at over 91 MPa.

This work improves on previous work from the same team where they used astronauts鈥� blood and urine as a binding agent. While the resulting material had a compressive strength of around 40 MPa, which is better than normal concrete, the process had the drawback of requiring blood on a regular basis. When operating in an environment as hostile as space, this option was seen as less feasible than using potato starch.

鈥淪ince we will be producing starch as food for astronauts, it made sense to look at that as a binding agent rather than human blood. Also, current building technologies still need many years of development and require considerable energy and additional heavy processing equipment which all adds cost and complexity to a mission. StarCrete doesn鈥檛 need any of this and so it simplifies the mission and makes it cheaper and more feasible.

鈥淎nd anyway, astronauts probably don鈥檛 want to be living in houses made from scabs and urine!鈥� Dr Aled Roberts, Research Fellow at the Future Biomanufacturing Research Hub, Swag直播 and lead researcher for this project.

The team calculate that a sack (25 Kg) of dehydrated potatoes (crisps) contain enough starch to produce almost half a tonne of StarCrete, which is equivalent to over 213 brick鈥檚 worth of material. For comparison, a 3-bedroom house takes roughly 7,500 bricks to build. Additionally, they discovered that a common salt, magnesium chloride, obtainable from the Martian surface or from the tears of astronauts, significantly improved the strength of StarCrete.

The next stages of this project are to translate StarCrete from the lab to application. Dr Roberts and his team have recently launched a start-up company, , which is exploring ways to improve StarCrete so that it could also be used in a terrestrial setting.

If used on earth, StarCrete could offer a greener alternative to traditional concrete. Cement and concrete account for about 8% of global CO₂ emissions as the process by which they are made requires very high firing temperatures and amounts of energy. StarCrete, on the other hand, can be made in an ordinary oven or microwave at normal 鈥榟ome baking鈥� temperatures, therefore offering reduced energy costs for production.

Oligonucleotides are a revolutionary new therapeutic in the pharma industry. These short, chemically synthesised fragments of DNA or RNA modulate protein expression through several different mechanisms to treat the underlying drivers of disease. This means almost limitless potential for treating conditions like heart disease, cancer, and muscular dystrophy.

There is, however, a risk that inefficiencies in the high cost, unsustainable process may limit patient access to oligonucleotide-based therapeutics at a large scale.

The new collaborative partnership builds on work at CPI鈥檚 Medicines Manufacturing Centre to revolutionise the manufacture of novel oligonucleotide-based medicines. The aim of this industry 鈥榞rand challenge鈥� is to develop an alternative process that is scalable, sustainable, and cost-effective.

The process in development uses bio-catalysis using a template that enables the building blocks of oligonucleotides to stitch together in a high-fidelity manner. This new enzyme-driven method has the potential to deliver oligonucleotides of superior purity to those made using chemical synthesis while reducing the carbon footprint of their manufacture. Ultimately, the successful commercialisation of this manufacturing approach would lower the cost of producing oligonucleotide-based therapeutics, removing a barrier to wider patient access.

The research will take place at the Swag直播 Institute of Biotechnology (MIB), part of Swag直播, which has been developing the technology to date.

Claire MacLeod, Oligonucleotides Grand Challenge Lead at CPI, said:

鈥淎s a technology innovation catalyst, bringing exemplary teams together to develop advanced technologies and manufacturing solutions that benefit people, and our planet, is what we do. This oligonucleotide project is a brilliant example of this. We are proud to bring our expertise in delivering collaborative innovation projects and our high-tech facilities to solve this grand challenge together with industry leading teams at MIB, AstraZeneca and Novartis.鈥�

Sarah Lovelock, Senior Lecturer at Swag直播 Institute of Biotechnology, said:

鈥淲e are excited to be involved in this partnership with leading industrial experts from CPI, AstraZeneca, and Novartis, to translate our approaches to oligonucleotide synthesis into sustainable manufacturing processes. We are hopeful that this collaboration will facilitate the large-scale production of oligonucleotides to ensure the widest possible access to this emerging class of therapeutics.鈥�

Barrie Cassey, Technology Lead 鈥� Medicines Manufacturing, at CPI, said:

鈥淐PI is a trusted delivery partner of the UK government鈥檚 Medicines Manufacturing Challenge and is well placed to lead the way in transforming the sustainability and viability of manufacturing technologies for this powerful new drug modality.

鈥淚n collaboration with our academic and industry partners, we aim to improve the processes for oligonucleotide manufacture to boost efficiency and sustainability across the pharmaceutical industry, and ultimately improve patient access to these life-changing medicines.

鈥淢any pharmaceutical companies have rich pipelines of oligonucleotide-based drug candidates that could benefit from an alternative production process. CPI and partners are keen to engage with pharma companies as the project develops the novel technology into a viable approach for oligonucleotide manufacture.鈥�

The , founded in 2020, is a global consortium of hundreds of scientists around the world with the collective goal of supporting euglenoid science through collaborative and integrative omics between academics and industry. Professor Rob Field, director of the Swag直播 Institute of Biotechnology, sits on the steering committee for the EIN and he and his lab will be part of the cross-discplinary network of scientists working to understand and discover the capabilities of the 800-strong species and strains of Euglena.

The EIN has today published a , outlining the case for a concerted effort to generate high quality reference genomes for the nearly 1,000 known species of euglenoids.

Euglenoids are part of the protist group, home to eukaryotic organisms that do not fit into animal, plant, or fungi groups. These diverse single-celled organisms are found in an exceptionally wide range of ecosystems around the world.

Multiple euglenoid species have translational applications, showing great promise in the production of biofuels, nutraceuticals, bioremediation, cancer treatments, and even as robotics design simulators. Their enormous potential has been largely untapped due to a lack of high-quality reference genomes.

Euglenoid genomes present a particular sequencing challenge because they are an example of secondary endosymbiosis 鈥� housing mitochondria, chloroplasts, and remnants of genetic material from organisms they enveloped to acquire these organelles.

As a result, fewer than 20 species have been explored at any level for translational potential through genomics. The EIN believes the time is right to address this.

Through generating high quality reference genomes for the known species of euglenoids, the EIN will work to:

• Understand the basic biology of euglenoids;
• Understand the evolution of euglenoids;
• Maximise euglenoid applications in ecological and environmental management;
• And explore, translate, and commercialise euglenoid products.

Data collected by the EIN will be openly available to the scientific community through the . Once in the ENA, annotated genomes can be imported into resources such as Ensembl Protists and presented in a uniform and FAIR way to research communities.

Professor Field's interest in this area goes back to 2015 when he and his lab were , including using it for creating a range of sugars and other natural products.  They've since gone on to which could prove useful for the pharmaceutical industry. Together with the rest of the network they hope to work together to better understand the more than 800 species of Euglena and exploit their potential. 

Dr. ThankGod Echezona Ebenezer, Founding President of EIN and a Bioinformatician at the European Bioinformatics Institute (EMBL-EBI), UK, said: 鈥淭he Euglena International Network will play a crucial role in helping to assemble specialists on euglenoids to increase our understanding of euglenoids biology and its translational applications. This could be useful to furthering our understanding of the evolution of parasitism, , , or supporting 鈥�.

The Euglena International Network is an affiliated network to the Earth BioGenome Project and the International Society of Protistologists.

Leading image photo credit: Bo偶ena Zakry艣, EIN photo contest winner 2021

Inline photo credit: Phillip Siambi, Caleigh Mitchell, Denise Gibbs, Ryan Cullen, Tracy Richardson and Scott Farrow

The beer is uniquely brewed using a novel strain of yeast, a hybrid, developed by the the (MIB) and Cloudwater.

鈥楾ales From The Future鈥� will be available in a limited batch directly from the Cloudwater website. The 750ml bottles are available to buy singly or as a pack. This Swag直播-made beer will also be available from Cloudwater鈥檚 taproom.

Budding yeast has been integral to beer brewing since its conception, and recent discoveries of new wild yeast species have paved the way for exploiting the extant biodiversity in strain development. In 2017, Professor Daniela Delneri, from the MIB, and her team, isolated a new natural yeast species, Saccharomyces jurei, high up in the foothills of the French Alps.

It is set apart from other similar brewing yeasts as it has the ability to thrive at lower temperatures, has a different flavour profile, and is able to ferment maltose and maltotriose, two abundant sugars present in the wort. This opened up an array of new possibilities for brewers, including the development of new breeding protocols to combine the S. jurei genome with the genomes of commercially available strains to create a multitude of hybrids with different fermentation characteristics.

It is from this discovery that Paul Jones, CEO of Cloudwater Brew Co. first saw the potential opportunity to work with the MIB to create a yeast specific to Cloudwater鈥檚 needs. In a recent study, supported by a Knowledge Transfer Partnership (KTP) with Cloudwater Brew Co., Delneri鈥檚 team and KTP Associate Konstantina Giannakou, they crossed this newly discovered yeast strain with a common ale yeast (Saccharomyces cerevisae) to produce new starter hybrid strains that could influence the aroma and flavour profile of the beer.

Paul said of the partnership: 鈥淲e are excited to be launching this beer following on from our work with Swag直播. This beer represents the possibilities of joining academia with industry and the importance of projects facilitated by this Knowledge Transfer Partnership. We cannot wait to share the fruits of our labour.鈥�

Professor Daniela Delneri says: 鈥淚t is brilliant to be able to work directly with Cloudwater Brew Co. to realise the potential of our new yeast species. Based on our work, S. jurei鈥檚 hybrids afford brewers more flexibility and options when brewing beers with different flavours and aromas. From here we can build on our work to create new yeast strains for different brewing needs.

鈥淚n fact, we have now also developed a method to turn typically sterile yeast hybrids into fertile cells able to produce a plethora of offspring which can be screened for desirable biotechnological traits. Such advances allow us to combine and select desirable traits from different yeast species via multigenerational breeding, paving the way for a swathe of new and exciting products鈥�.

To launch the beer, Cloudwater Brew Co., in partnership with the MIB, will be hosting an event at the Cloudwater Taproom on Thursday 25 August.  Additionally, at 7pm a dedicated tasting session will take place where 鈥楾ales From The Future鈥� will feature alongside five other beers from the Barrel Project. More information

To illustrate the utility of their platform, they have engineered an enzyme that can successfully degrade poly(ethylene) terephthalate (PET), the plastic commonly used in plastic bottles. 

In recent years, the enzymatic recycling of plastics has emerged as an attractive and environmentally friendly strategy to help alleviate the problems associated with plastic waste. Although there are a number of existing methods for recycling plastics, enzymes could potentially offer a more cost-effective and energy efficient alternative. In addition, they could be used to selectively breakdown specific components of mixed plastic waste streams that are currently difficult to recycle using existing technologies.  

Although promising as a technology, there are considerable hurdles that need to be overcome for enzymatic plastic recycling to be used widely on a commercial scale. One challenge, for instance, is that natural enzymes with the ability to break down plastics typically are less effective and are unstable under the conditions needed for an industrial-scale process.  

To address these limitations, in a paper released today in , researchers from Swag直播 have reported a new enzyme engineering platform that can quickly improve the properties of plastic degrading enzymes to help make them more suitable for plastic recycling at large scales. Their integrated and automated platform can successfully assess the plastic degradation ability of around 1000 enzyme variants per day.  

Dr Elizabeth Bell, who led the experimental work at the MIB, says of the platform; 鈥�The accumulation of plastic in the environment is a major global challenge. For this reason, we were keen to use our enzyme evolution capabilities to enhance the properties of plastic degrading enzymes to help alleviate some of these problems.  We are hopeful that in the future our scalable platform will allow us to quickly develop new and specific enzymes are suitable for use in large-scale plastic recycling processes.鈥�

To test their platform, they went on to develop a new enzyme, HotPETase, through the directed evolution of IsPETase. IsPETase is a recently discovered enzyme produced by the bacterium Ideonella sakaiensis, which can use PET as a carbon and energy source. 

While IsPETase has the natural ability to degrade some semi-crystalline forms of PET, the enzyme is unstable at temperatures above 40掳C, far below desirable process conditions. This low stability means that reactions must be run at temperatures below the glass transition temperature of PET (~65掳C), which leads to low depolymerisation rates. 

To address this limitation, the team developed a thermostable enzyme, HotPETase, which is active at 70掳C, which is above the glass transition temperature of PET.  This enzyme can depolymerise semi-crystalline PET more rapidly than previously reported enzymes and can selectively deconstruct the PET component of a laminated packaging material, highlighting the selectivity that can be achieved by enzymatic recycling.  

 Professor Anthony Green, Lecturer in Organic Chemistry, said: 鈥�The development of HotPETase nicely illustrates the capabilities of our enzyme engineering platform. We are now excited to work with process engineers and polymer scientists to test our enzyme in real world applications.  Moving forward, we are hopeful that our platform will prove useful for developing more efficient, stable, and selective enzymes for recycling a wide range of plastic materials.鈥�

The development of robust plastic degrading enzymes such as HotPETase, along with the availability of a versatile enzyme engineering platform, make important contributions towards the development of a biotechnological solution to the plastic waste challenge. To move this promising technology forward will now require a collaborative and multidisciplinary effort involving biotechnologists, process engineers and polymer scientists from across the academic and industrial communities. With the world facing an ever-mounting waste problem, biotechnology could provide an environmentally sustainable solution. 

Biotechnology is one of the University鈥檚 research beacons 鈥� exemplars of interdisciplinary collaboration and cross-sector partnerships that lead to pioneering discoveries and improve the lives of people around the world. manchester.ac.uk/biotechnology-research  

The newly created hybrid yeast strains have been shown to successfully breed and produce offspring with specific desirable characteristics required for the beverage manufacturing process.

Naturally, hybrid yeasts are infertile, and their specific characteristics cannot be passed on. This previously required brewers to use selective methods to achieve the desired traits and has meant that the fermentation industries have so far missed out on potential new characteristics that the large genetic diversity of yeast hybrids affords.

The type of yeast used in the fermentation process influences how a beer tastes once it has been brewed. There are currently two main categories of yeasts, ale and lager, plus hundreds of variations used by modern day brewers in a booming global industry. Developing yeasts to give new flavours has been a goal of many brewers since the 1800s.

Now, as reported in the (PNAS), Professor Daniela Delneri, Professor of Evolutionary Genomics at the  and her team have succeeded in producing fertile yeast hybrids that are able to breed and generate a large number of progenies with diverse genetic traits.

Professor Delneri, lead author of the research said: “This research tackles the fundamental issue of hybrid sterility and multigenerational breeding. With my colleague Professor Ed Louis at the University Leicester, we were able to overcome species barriers and pinpoint the genetic traits unique to the hybrids. This technology has the ability to revolutionise the current practices for strain selection by allowing, via breeding, the rapid creation of efficient tailored yeasts carrying specific, novel, and important traits.

"As well as opening opportunities in food and drink production, this approach could be used to develop novel yeast “cell factories” that could be used in the field of industrial biotechnology to sustainably biomanufacture pharmaceuticals, chemicals and fuels.”

This research demonstrates how the potential for enhancing natural biodiversity and developing new hybrids is greater than expected and will offer new ways for industry to generate new and exciting consumer choices.

This research was carried out as part of a BBSRC-funded project in collaboration with SAB-Miller and – the world’s largest brewer. It also featured as part of the EU .

Dr. Philippe Malcorps, AB-InBev ‘yeast guru’, said "We are excited by these findings and pleased to have been able to support this research. The proof of concept opens doors to new innovations we can bring to our portfolio offering exciting new flavours via fermentation."

PET plastic has long been a concern due to the sheer volume of plastic created globally and its impact through non-recycled waste on the environment of drinking bottles, take-away containers and micro plastics.

Part of the reason plastic is difficult to break down is its chemical structure, which is made up of monomers – small molecules which are bonded together to form polymers. To date there have been many studies on the ability of bacteria to degrade PET plastic down into the constituent monomers. However, there has been limited study on the ability of these bacteria to recognise and uptake the corresponding monomers into their cells.

In new research published today in the journal, , researchers from studied the recognition potential of a key protein involved in cellular uptake of the monomer terephthalate (TPA), by the solute binding protein TphC.

and often plastic packaging is used only once. Despite a rise in home and industrial recycling efforts there still exists a systemic problem but also a business opportunity. Developing microbial degradation of plastics could be key in tackling this global issue.

The Swag直播 team used biochemical and structural techniques to determine how the substrate, TPA is recognised by TphC. Dr Neil Dixon, lead author of the research said: “Understanding how bacteria recognise and degrade xenobiotic chemicals, is important both from an ecological and biotechnological perspective. Understanding at a molecular level how these plastic breakdown products are imported into bacteria cells means that we can then use transporters in engineered cells for bioremediation applications to address pressing environment concerns.”

Using techniques which allowed the team to visualise the TphC in both open and closed conformations upon TPA binding, they then used genome mining approaches to discover homologous transporter proteins and also enzymes involved in TPA breakdown and assimilation.

These mined genomic parts provide a genetic resource for future biotechnological and metabolic engineering efforts towards circular plastic bio-economy solutions. There is great interest and potential in the use of engineered enzymes and microbes to degrade and assimilate waste plastic.

These new findings will now support the development engineered microbial cells for bio-remediation and bio-based recycling of plastic waste.

The paper, , is published in the journal Nature Communications.

Biotechnology is one of Swag直播’s - examples of pioneering discoveries, interdisciplinary collaboration and cross-sector partnerships that are tackling some of the biggest questions facing the planet. #ResearchBeacons

The newly published findings are the result of collaborative work between Global Bioenergies and the team of Dr. David Leys at Swag直播, and have been published today in . This paper describes the evolution and mechanism of isobutene forming enzymes far superior to previously used catalysts. Isobutene is a high value gaseous hydrocarbon, and one of the major building blocks of the petrochemicals industry: 15 million tonnes are produced every year to yield cosmetic ingredients, rubber and fuels.

This is the first time a member of a widespread enzyme family that depends on an unusual vitamin B2 derivative has been repurposed to yield isobutene. This has been made possible through the extensive work performed on both sides of the Channel, with laboratory guided evolution carried out at Global Bioenergies, and detailed structure analysis of the the evolved enzymes at Swag直播.

David Leys, group leader at the Swag直播 Institute of Biotechnology of Swag直播, says: 鈥淥ur collaboration with Global Bioenergies on the subject of isobutene production combines in a unique manner quantitative molecular bioscience and industrial, high-throughput approaches. It is very satisfying to see how fundamental understanding of these enzymes obtained with European Research Council funding supports industrial application. The evolved enzymes represent several orders of magnitude improvement in the efficiency of isobutene bioproduction, directly contributing to an economically viable and renewable process, and thus a more sustainable future.鈥�

Marc Delcourt, co-founder and CEO of Global Bioenergies, adds: 鈥�Nature Communications stands among the high-class peer-reviewed scientific journals. We are very pleased to see the work we conducted jointly with the team of Dr David Leys reaches such a striking scientific recognition. The evolved enzymes, on which GBE holds exclusive intellectual property rights for the isobutene production, will have a significant role in the environmental transition our world is now engaged in.鈥�

As an alternative to fossil fuel derived isobutene, Global Bioenergies assembled a modified pathway for the production of isobutene from glucose. The crucial final step yielding the desired product makes use of a decarboxylase enzyme. This particular enzyme has been evolved from naturally occuring microbial decarboxylases that depend on an elaborately modified Vitamin B2 (called prenylated flavin or prFMN) for activity.

The Swag直播 group has been at the forefront of studying these prFMN-dependent catalysts, and determined structure and biochemical properties of isobutene yielding enzymes evolved by Global Bioenergies. The company screened an enzyme library for inherent isobutene production activity, and used directed evolution to yields variants with up to an 80-fold increase in activity. Structure determination of the evolved catalysts reveal that changes in the enzyme pocket are responsible for improved production, while solution and computational studies suggest that isobutene release is currently the limiting factor.

Global Bioenergies has developed a unique conversion process for renewable resources into isobutene, one of the main petrochemical building blocks that can be converted into ingredients for cosmetics, petrol, kerosene, LPG and plastics.

The key topics that will be discussed include:

• Emerging trends in research and development
• Data reporting, survey and statistics
• Analysis of sectors including life sciences, manufacturing, agriculture, and energy
• Emerging technologies, such as automation, AI and VR

Professor Scrutton will be joined by policymakers such as Nadhim Zahawi MP, Minister for BEIS and COVID-19 Vaccine Deployment, and Chi Onwurah MP, Shadow Minister for Science, Research and Digital, as well as business leaders such as Andy Topping, Chief Scientific Officer at Fujifilm Diosynth Biotechnologies, and sector specialists such as Professor Lionel Clarke, Chair of the UK Synthetic Biology Leadership Council.

The live panel and Q&A will discuss how UK industry - responsible for a quarter of the UK's greenhouse gas emissions - can use biotechnology to reduce its carbon footprint and contribute to the UK's net zero goals. Specifically, they will focus on how biotechnology can create more sustainable chemicals for agriculture, more efficient and greener fuels for transport, and close the gap in our economy to create a circular economy.

The event will start at 2.30pm on Thursday, 15 July. To book tickets, please .

For more information about how Swag直播鈥檚 biotechnology research is supporting the UK's net zero goals, please visit the net zero campaign page.

Biotechnology is one of the University's research beacons - examples of pioneering discoveries, interdisciplinary collaboration and cross-sector partnerships that are tackling some of the biggest challenges facing the planet.

, led by Harvard’s Wyss Institute for Biologically Inspired Engineering in collaboration with the Laboratory of Soft Biolectronic Interfaces at EPFL in Lausanne and Swag直播’s National Graphene Institute (NGI), mixed carbon nanotubes with a water-based, defect-free solution of graphene, by a team led by Professor Cinzia Casiraghi.

Electrodes are frequently used in medicine to monitor or deliver electrical impulses inside and outside the human body, however performance is currently limited by the rigidity of devices that do not match the soft springiness of living tissue, a property known as viscoelasticity. Electrodes may detach under movement or require greater current to affect their intended target because their shape does not fit precisely to the host site.

The key, according to lead authors Ms Christina Tringides and Professor David Mooney from Harvard, was a hydrogel that could mimic the viscoelasticity of tissue, alongside a conductive ink that could also perform well under flexion.

Replacing rigid metals

Tringides and Mooney, in collaboration with the  in Swag直播, identified a mixture of graphene flakes and carbon nanotubes as the best conductive filler, replacing the use of traditional rigid metals.

“Part of the advantage of these materials is their long and narrow shape," explained Tringides. "It’s a bit like throwing a box of uncooked spaghetti on the floor – because the noodles are all long and thin, they’re likely to cross each other at multiple points. If you throw something shorter and rounder on the floor, like rice, many of the grains won’t touch at all.”

While the carbon nanotubes used are commercially available, the graphene flake suspension is a process patented by Swag直播, currently exploited for printed electronics and biomedical applications. This work demonstrated that you need both materials to achieve optimal electrode performance - carbon nanotubes or graphene alone would not suffice.

Cinzia Casiraghi, Professor of Nanoscience from the NGI and Department of Chemistry at Swag直播, said: “This work demonstrates that high-quality graphene dispersions - made in water by a simple process based on a molecule that one can buy from any chemical supply - have strong potential in bioelectronics. We are very interested in exploiting our graphene (and other 2D materials) inks in this field.”

Collaborative effort

Kostas Kostarelos, Professor of Nanomedicine and leader of the Nanomedicine Lab, added: “This truly collaborative effort between three institutions is a step forward in the development of softer, more adaptable and electroactive devices, where traditional technologies based on bulk and rigid materials cannot be applied to soft tissues such as the brain.”

This research in Swag直播 was supported by the EPSRC Programme Grant  and the International Centre-to-Centre grant with Harvard. Other funders include the: National Science Foundation, National Institutes of Health, Wyss Institute for Biologically Inspired Engineering at Harvard University, National Institute of Dental & Craniofacial Research, Eunice Kennedy Shriver National Institute of Child Health & Human Development, Bertarelli Foundation, Wyss Center Geneva, and SNSF Sinergia. 

Advanced materials is one of Swag直播’s research beacons - examples of pioneering discoveries, interdisciplinary collaboration and cross-sector partnerships that are tackling some of the biggest questions facing the planet. #ResearchBeacons

[Main image copyright of Wyss Institute at Harvard University]

This prestigious accolade rewards an outstanding contribution made to the UK by an academic institution. The work of the University鈥檚 (MIB) is being celebrated by the most recent round of awards, which mark the period 2018-2020.

With the challenge of climate change propelled to the top of political, social and economic agendas, Swag直播 is at the heart of helping to design a sustainable future for the UK and communities across the world.

Experts at the University are looking to develop disruptive bio-based technologies that will transition chemicals manufacture from petrochemicals to sustainable biomanufacturing by connecting the University鈥檚 strengths in discovery science directly with industrial partners.

This partnership approach will help stimulate innovation and drive a new bioeconomy that will position Swag直播 and the UK as a whole as leaders of green growth by supporting biomanufacture in key areas such as advanced materials, pharmaceuticals, value added chemicals and the next generation of biofuels.

鈥淚t鈥檚 a great honour to have been awarded a Queen鈥檚 Anniversary Prize for Higher and Further Education which is viewed as the most prestigious form of national recognition open to a UK university or college,鈥� said Professor Dame Nancy Rothwell, President and Vice-Chancellor of Swag直播.

鈥淥ur Swag直播 model of innovation enables us to take cutting-edge science and, by working strategically with our commercial and other partners, transfer research breakthroughs into real world applications. It鈥檚 this approach that is now helping to position Swag直播 at the vanguard of clean economic growth.

鈥淟eadership from Professor Nigel Scrutton at the University鈥檚 and the enterprising vision of his team have played a critical role in this success story.鈥�

Professor Martin Schr枚der, Vice-President of Swag直播 and Dean of the Faculty of Science and Engineering, added that it was with real pride that the Faculty had been recognised in this way.

Professor Schr枚der said this latest prize follows similar accolades for the University鈥檚 science and engineering community during the past decade. In 2011 it was announced that the University鈥檚 Dalton Nuclear Institute was a winner of the Diamond Jubilee Queen鈥檚 Anniversary Prize and then in 2014 a Queen鈥檚 Anniversary Prize for Higher and Further Education (2012-2014) was awarded in recognition of .

Professor Schr枚der added: 鈥淭he science and engineering community at Swag直播 continually demonstrate how our research is able to make our world work better.

鈥淚 am delighted that Professor Nigel Scrutton and the excellent team at the Swag直播 Institute of Biotechnology have been the latest recipients of this prestigious award. Their work is really helping to put Swag直播, and the UK as whole, on the international map for Industrial Biotechnology at a critical time for our planet鈥檚 future wellbeing.鈥�

Professor Nigel Scrutton also added: 鈥�I am delighted that the Swag直播 Institute of Biotechnology has been recognised in this way.

鈥淢y thanks go to all colleagues who have contributed to MIB鈥檚 work, especially over the last decade during my time as MIB Director. Given the current challenges facing our planet the importance of the bioeconomy is clear to see.

鈥淚 am proud that MIB is finding unique science and technology solutions to meet these challenges and is contributing to clean growth across multiple sectors.鈥�

Further evidence of Swag直播鈥檚 leadership in Industrial Biotechnology was the recent launch of the new Future Biomanufacturing Research Hub which is backed by 拢10 million in government investment to develop new technologies in order to transform the manufacturing processes of chemicals by using plants, algae, fungi, marine life and micro-organisms.

This pioneering Swag直播-based hub will work alongside partner spoke organisations: Imperial College London, University of Nottingham, University College London, the UK Catalysis Hub, Industrial Biotechnology Innovation Centre and the Centre for Process Innovation. A Swag直播 conference to launch the Hub was attended by many industrial partners, including global brands such as Shell, GSK, Unilever and BP.

The Swag直播 research group, led by Professor Nigel Scrutton, Director of the and supported by the prestigious US-based international maritime research agency Office of Naval Research Global (ONR), is using synthetic biology to help identify a more efficient and sustainable method to make biofuel than the one currently used.

Scientists have discovered that the bacteria species called Halomonas, which grows in seawater, provides a viable 鈥渕icrobial chassis鈥� that can be engineered to make high value compounds. This in turn means products like bio-based jet fuel could be made economically using production methods similar to those in the brewery industry and using renewable resources such as seawater and sugar.

The breakthrough behind this approach is the ability to re-engineer the microbe鈥檚 genome so to change its metabolism and create different types of high value chemical compounds which could be renewable alternatives to crude oil. Dr Benjamin Harvey and his team of researchers at the world-leading Naval research facilities in China Lake, California, USA, have pioneered this exciting work on converting biological precursors to relevant jet fuels.

Following on from this research, explained: 鈥淓ffective biofuels strategies require the economic production of fuels derived from a robust microbial host on a very large scale 鈥� usually cultivated on renewable waste biomass or industrial waste streams - but also with minimal downstream processing and avoids use of fresh water. With Halomonas these requirements can be met, so minimizing capital and operational costs in the production of these next generation biofuels.鈥�

This research could be groundbreaking news for the wider biofuels industry. 鈥淚n the case of the jet fuel intermediates we are bio-producing, they are chemically identical to petrochemical derived molecules, and will be able to 鈥榙rop-in鈥� to processes developed at China Lake,鈥� added Dr Kirk Malone, Director of Commercialisation at Swag直播鈥檚 MIB.

Dr Malone said unlike the biofuels we know today, which are dependent on agricultural land to produce corn and sugar beets, bio-production in seawater would avoid ethical concerns of 鈥榝uel vs food鈥�. Moreover, the final products would be identical to today鈥檚 fuels, allowing automobiles to maintain the same high performance standards without having to redesign the engine to consume lower quality fuels.

Also of interest for Swag直播 is the application of this process to many other diverse industries, specifically those that rely on crude oil to generate a wide array of products such as cosmetics, fragrances and flavors.

鈥淔or example, if you think about rosehip oil extraction - you need to plant hundreds of acres of flowers and then collect the flowers, squeeze the oil from the rose petals to process minute amounts for making the fragrance,鈥� explained Patrick Rose, Science Director for ONR Global in London.

鈥淚t is economically very expensive, land and resource intensive, subject to the climate for harvesting, when those resources could instead be employed for more sustainable agriculture

鈥淚t is possible to replicate the exact same molecules we harvest from crops to make high value compounds by exploiting this biological process by taking the genes out of the plant and inserting the information into bacteria. With this engineering feat, there is no dependence on environmental factors and an increased level of reliability in the product.鈥�

Although the chemical industry has improved its chemical synthesis processes during the past century, there are environmental and economic concerns to the way chemistry is still performed. Engineering bacteria to replicate the same processes can be significantly more sustainable, reduce waste streams, limits the production of toxic byproducts, and is not dependent on non-sustainable resources such as crude oil.

What is unique about this platform developed by Swag直播 group is that the bacteria grow in seawater. The management of the system and its durability are also game changers, with a very long life span for continuous production.

鈥淏iotechnology allows us to harness the exquisite selectivity of nature to efficiently produce complex chemicals, often using temperatures and pressures lower than in traditional organic synthesis. This can result in fewer by-products and contaminants (i.e. trace metals from catalysts), thereby simplifying purification and lowering costs,鈥� added reveals Dr. Kirk Malone, Director of Commercialisation of MIB.

Synthetic biology is taking engineering principles and applying them to biology; an interdisciplinary field in constant search of the next revolutionary discovery.

is one of Swag直播鈥檚 - examples of pioneering discoveries, interdisciplinary collaboration and cross-sector partnerships that are tackling some of the biggest questions facing the planet. #ResearchBeacons

Researchers at the Universities of Swag直播 and York found the enzyme in Aspergillus oryzae, a kind of fungus used for making soy sauce. The discovery,  was published in .

The enzyme鈥檚 greatest impact could be in a class of medications called monoamine oxidase (MAO) inhibitors. One such example of this kind of drug is Rasagiline. Rasagiline helps Parkinson sufferers by increasing a substance in the brain that affects motor function.

These substances help reduce the involuntary tremors that are associated with the condition. The medicine works in both early and advanced Parkinson鈥檚, and is especially useful in dealing with non-motor symptoms of the condition, like fatigue.

The team, led by Professor Nick Turner, Professor of Chemical Biology from the Swag直播 Institute of Biotechnology (MIB), have identified a new biocatalyst (RedAm) that accelerates a process called reductive amination.

Reductive amination is one of the most important methods for the synthesis of chiral amines, which are important chemical building blocks in the production of pharmaceutical products.

The discovery of RedAms means more efficient routes for chiral amine synthesis, including medications such as Rasagiline. The application of RedAms will result in a dramatic reduction in time required for synthesis which will also have a positive impact on the costings and manpower needed to produce chiral amines.

A recent analysis of drugs approved by America鈥檚 Food and Drug Administration (FDA) found that approximately 40 percent of new chemical entities (NCEs) contain one or more chiral amine building blocks. This means this new enzyme could also be key to improving the manufacture of numerous other medications on the market treating multiple conditions.

There is currently no cure for Parkinson's, but there are a range of treatments to control the symptoms. However, medication such as Rasagiline is the main treatment for Parkinson's. Every hour, someone in the UK is told they have Parkinson's. One person in every 500 has Parkinson's. That's about 127,000 people in the UK.

Professor Nick Turner said: 鈥楾his is a very exciting discovery from both a chemistry and pharmaceutical perspective. It is the first enzyme of its kind that has these properties and has the potential to improve the production of this and other important drugs.鈥�

Scientists at Swag直播 have made an important discovery that forms the basis for the development of new applications in biofuels and the sustainable manufacturing of chemicals.

Based at the Swag直播 Institute of Biotechnology (MIB), researchers have identified the exact mechanism and structure of two key enzymes isolated from yeast moulds that together provide a new, cleaner route to the production of hydrocarbons. 

Published in Nature, the research offers the possibility of replacing the need for oil in current industrial processes with a greener and more sustainable natural process.

Lead investigator , explains the importance of his work: 鈥淥ne of the main challenges our society faces is the dwindling level of oil reserves that we not only depend upon for transport fuels, but also plastics, lubricants, and a wide range of petrochemicals. Solutions that seek to reduce our dependency on fossil oil are urgently needed.鈥�  

He adds: 鈥淲hilst the direct production of fuel compounds by living organisms is an attractive process, it is currently not one that is well understood, and although the potential for large-scale biological hydrocarbon production exists, in its current form it would not support industrial application, let alone provide a valid alternative to fossil fuels.鈥�

Professor Leys and his team investigated in detail the mechanism whereby common yeast mould can produce kerosene-like odours when grown on food containing the preservative sorbic acid. They found that these organisms use a previously unknown modified form of vitamin B2 (flavin) to support the production of volatile hydrocarbons that caused the kerosene smell. Their findings also revealed the same process is used to support synthesis of vitamin Q10 (ubiquinone).  

Using the Diamond synchrotron source at Harwell, they were able to provide atomic level insights into this bio catalytic process, and reveal it shares similarities with procedures commonly used in chemical synthesis but previously thought not to occur in nature.  

Professor David Leys says: 鈥淣ow that we understand how yeast and other microbes can produce very modest amounts of fuel-like compounds through this modified vitamin B2-dependent process, we are in a much better position to try to improve the yield and nature of the compounds produced.鈥�

In this particular study, published in the journal Nature, researchers focussed on the production of alpha-olefins; a high value, industrially crucial intermediate class of hydrocarbons that are key chemical intermediates in a variety of applications, such as flexible and rigid packaging and pipes, synthetic lubricants used in heavy duty motor and gear oils, surfactants, detergents and lubricant additives.  

Professor Leys concludes: 鈥淭his fundamental research builds on the MIB鈥檚 expertise in enzyme systems and provides the basis for the development of new applications in biofuel and commodity chemical production. The insights from this research offer the possibility of circumventing current industrial processes which are reliant on scarce natural resources.鈥�

Notes for editors

The research team was made up of researchers from the new BBSRC/EPSRC Centre for Synthetic Biology of Fine and Speciality Chemicals based at the Swag直播 Institute of Biotechnology (MIB) and comprises interdisciplinary scientists from across the Faculties of Life Sciences and Engineering and Physical Sciences.

This research was supported by the BBSRC (Biotechnology and Biological Sciences Research Council) and made possible with access to Diamond beamlines.

This study resulted in back-to-back publications in the journal Nature: 

Paper 1
White, M. D. et al. 鈥淯biX is a flavin prenyltransferase required for bacterial ubiquinone biosynthesis鈥� will be published in Nature on Wednesday 17 June 2015. Advance Online Publication (AOP) on  
Paper doi: http://dx.doi.org/10.1038/nature14559 
This manuscript explains how the vitamin B2 is modified and thereby recruited in bacterial vitamin Q biosynthesis.

Paper 2
Payne, K.A.P. et al. 鈥淣ew cofactor supports alfa-beta-unsaturated acid decarboxylation via 1,3-dipolar cycloaddition鈥� will be published in Nature on Wednesday 17 June 2015.  Advance Online Publication (AOP) on
Paper doi:
This manuscript establishes how the modified B2 is used to support the fuel-like compound production.

More information about the Swag直播 Institute of Biotechnology can be found at

Professor Leys is available for interview on request.

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Tel: +44 (0)161 275 8383
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