Collaboration Agreement Signed with AstraZeneca

Oxford Biomedica PLC 14 February 2000 For further information, please contact: Oxford BioMedica plc Professor Alan Kingsman, Chief Executive Tel: +44 (0)1865 783 000 City / Financial Enquiries David Simonson / Melanie Toyne Sewell Tel: +44 (0)171 606 1244 Scientific / Trade Press Enquiries Sue Charles / Sarah Pattinson, HCC de Facto Tel: +44 (0)171 496 3300 OXFORD BIOMEDICA ANNOUNCES COLLABORATION WITH ASTRAZENECA AND THE ESTABLISHMENT OF A DRUG DISCOVERY UNIT Second agreement in the genomics field based on BioMedica's LentiVector(TM) Technology Oxford, UK - 14 February 2000: Oxford BioMedica plc announced today that it has signed a collaboration agreement with the Loughborough based AstraZeneca R&D Charnwood in the fields of genomics and target validation. The joint programme will explore the use of BioMedica's proprietary LentiVector(TM) gene delivery technology to deliver genes to primary cells that are central to a number of disease processes, including asthma. This deal is BioMedica's third collaboration that makes use of its core gene therapy technologies for drug discovery programmes outside the field of gene therapy. The other two collaborations are with Rhone-Poulenc Rorer and make use of the Company's gene control technology in drug screens and LentiVectors(TM) for target validation. The interest in BioMedica's technology for drug discovery is such that the Company has established a new Unit of Drug Discovery under the directorship of Dr Kyriacos Mitrophanous and Dr Miles Carroll, two of Oxford BioMedica's senior scientists. The Unit is completely self-financing and will develop technologies and approaches that arise out of the Company's core technologies. There are immediate opportunities in the fields of LentiVector(TM) gene transfer, hypoxia control and MacroGen(TM), the Company's proprietary macrophage delivery technology. Commenting on the agreement with AstraZeneca Alan Kingsman, BioMedica's Chief Executive said: 'We are pleased to be collaborating with AstraZeneca for the first time. The deal adds further confirmation that our technology is not only at the forefront of gene therapy, but that it can also be applied to the new field of gene-driven drug discovery. It is also recognition of our very strong position in this field, having several layers of robust patent applications covering commercially valuable lentiviral vector systems. We have good reason to believe that these systems are not covered by any other company's existing patents. 'Efficient, safe and regulated gene delivery is required for both effective gene therapy and for key aspects of the difficult task of unravelling information generated by the various genomics and proteomics programmes. Our gene transfer systems deliver these key features which are required by the major pharmaceutical companies. We anticipate further commercial opportunities arising from LentiVectors(TM) and other technologies from our new drug discovery unit' Notes to Editors 1. Oxford BioMedica plc Established in 1995, the Company specialises in the development and application of gene-based therapeutics using advance gene delivery technologies for the treatment of disease in the areas of oncology, viral infection and neurodegenerative disease. Oxford BioMedica plc was floated on the UK Alternative Investment Market of the London Stock Exchange in December 1996. 2. AstraZeneca AstraZeneca is a major international healthcare business engaged in the research, development, manufacture and marketing of ethical (prescription) pharmaceuticals and the supply of healthcare services. It is one of the top five pharmaceutical companies in the world with healthcare sales of $13 billion and leading positions in sales of gastrointestinal, oncology, anaesthesia including pain management, cardiovascular, central nervous system (CNS) and respiratory products. 3. Genomics and proteomics The exploitation of the knowledge of gene sequences and the pattern of expression of proteins are called genomics and proteomics respectively. These two areas generate a vast amount of data describing correlations between the expression of genes and particular diseases. However, although these approaches are extremely powerful, they only yield correlations, not causative, mechanistic relationships between gene expression and disease. As a result, the challenge facing the industry is to establish, from a large number of correlations, those genes with a causative relationship to disease which should be the target for drug development. The process of identifying genes linked to disease is known as target validation. 4. Target validation This involves taking candidate genes and putting them into cells, either in culture or in animal models, and establishing whether the presence of that gene produces an effect that is linked to disease. If it does, then that gene is validated as a target for further drug development. The process of gene validation is costly and time consuming and the pharmaceutical industry has invested heavily in genomics and proteomics programmes with major collaborations in both fields. Many also have allocated substantial in-house resources to these activities. As a result, the industry is constantly looking for better ways of validating targets, which is why the application of the lentiviral vector system may make a considerable contribution. 5. Lentivirus vector systems and the process of drug discovery. In the process of target validation, it is very important that the vehicle that delivers the candidate gene, the vector, produces no effect in the cell that might be confused with the effects of the candidate gene. This is where the LentiVector(TM) technology is so powerful. Lentiviruses, which form the basis of LentiVector(TM) technology, have similar features to retroviruses in the ease of manipulation, predictable integration and reliable gene expression and regulation. However, their main advantage over retroviruses is the ability to function in non-dividing cells or cells that are dividing slowly. This is a particular feature of many cells that have been identified by the pharmaceutical industry as important targets for drug discovery and development. In addition, not only do LentiVectors(TM) deliver genes efficiently to many cell types that are important in disease processes but they generate no detectable adverse effects on the cell or tissue that receives the candidate gene. Effects that are seen in such experiments can be attributed, therefore, to the gene alone. 6. Worldwide web This release is also available on the Worldwide Web at http://www.oxfordbiomedica.co.uk