New international partnership promises great potential for next-generation biopharmaceuticals
There are a multitude of challenges associated with the production of next-generation biopharmaceuticals and vaccines. The Austrian Centre of Industrial Biotechnology and the BOKU - University of Natural Resources and Life Sciences, Vienna together with the Boyce Thompson Institute (BTI) Ithaca, NY are developing a new production platform that promises faster, more economic and safer production of modern pharmaceuticals - from gene therapies for neurodegenerative disorders such as Parkinson's or Alzheimer's, to cancer therapy and modern preventive vaccines against influenza, HIV, dengue or zika virus.
Modern biopharmaceuticals are often based on the mass production of designer proteins, such as virus-like particles (VLP) for gene therapy or for the development of vaccines, to support the organism in producing antibodies against various pathogens. Imagine the immune system as a memory match player busily identifying the surfaces of any virus that appears and developing resistances as soon as it gets into contact with the virus. VLP make use of this principle: they imitate the surface of the virus and feign an infection without damaging the body, because the dangerous genetic material inside the virus envelope that is responsible for infection, has been removed.
Since the surface proteins of VLP can be tailored to various applications, this technology is becoming ever more interesting for industry. However, the production of this specialized biomolecules calls for improved and above all, more robust production procedures.
Conventional production procedures have significant disadvantages
For fifty years, vaccines have been produced by means of seed viruses. These are living pathogens that multiply in cells from chicken eggs. Seed viruses are used, for example, to produce approved influenza vaccines. The rule of thumb "one vaccine dose per egg" means that the number of vaccines is limited to 150 to 200 million available eggs worldwide. Formerly used alternative platforms - such as vaccine production in cultured cell lines of eukaryotic organisms such as yeasts and insects - have the disadvantage of instability.
New virus-free insect cell line
In a joint project, the Austrian Centre of Industrial Biotechnology (acib) and the Boyce Thompson Institute (BTI) at Cornell University are investigating a platform technology for the optimised production of diverse proteins. "This has become possible thanks to a cell line developed by BTI that for the first time is free of a certain type of insect virus that has been an issue for these cells in the past", explains acib researcher and project manager Reingard Grabherr.
The process is currently being tested on pilot-plant-scale by acib. Using a sophisticated fermentation process, the genetically optimised insect cell line is stimulated to grow and produce protein in a bioreactor, before the scientists introduce the genetic information for the generation of designer proteins, which are purified from the insect cells after several days of production.
"Through cooperation with acib, BTI researchers are able to observe the new cell lines under conditions that normally prevail in commercial production. Testing the new technology in these conditions is novel for the university environment", said Paul Debbie, Director of technology transfer and licensing at BTI, who is pleased about this opportunity. Remarking on the value of collaboration for scaling up, Debbie said, "acib's capabilities are far beyond anything that we have here at BTI where we are mainly working at laboratory scale."
Major potential for biopharmaceutical industry
In a next step, researchers aim to prepare the pilot-production platform for industrial application, but to do so they must first carefully observe how the scaled-up process has affected the cell lines at a genetic level. "To achieve even higher process reliability and prevent losses, we carry out transcriptomics analyses and check how the 15,000 different genes of the cell behave", Wolfgang Ernst, researcher at acib, explains.
"As a new platform technology, the process entails great potential for the pharmaceutical industry", Alois Jungbauer explains. He is area leader at acib and researcher at the BOKU and has already established contact to interested international companies.
A wide range of next-generation biopharmaceuticals could be produced with the new technology in a few years and in a much faster, simpler and safer manner. Improved production of VLPs and other designer proteins will open the doors to a promising future of gene therapies for neurodegenerative disorders including Parkinson's or Alzheimer's, cancer therapy, and long-awaited preventive vaccines.
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About acib
The Austrian Centre of Industrial Biotechnology (acib) is an international Research Centre for Industrial Biotechnology with locations in Vienna, Graz, Innsbruck, Tulln, Vienna (A), Hamburg, Heidelberg, Bielefeld (D), Pavia (I) and Barcelona (E), Canterbury (AUS), New Zealand (NZL) and Taiwan. Using the concepts of nature, acib-scientists replace traditional industrial methods with new, more economic and ecological technologies.
Actually, acib is an international network of 150+ international universities and industry partners, including BASF, DSM, Sandoz, Boehringer Ingelheim RCV, Jungbunzlauer or VTU Technology. Owners are the Universities of Innsbruck and Graz, Graz University of Technology, the University of Natural Resources and Life Sciences, Vienna and Joanneum Research.
At acib 250+ scientific employees with up to 30+ years of experience in industrial biotechnology work in more than 170 research projects. The competence center acib is sponsored within COMET (Austrian Competence Centres for Excellent Technologies) by the BMVIT, BMWFW and the provinces of Styria, Tyrol, Lower Austria and Vienna. The COMET program is handled by the FFG.
About BTI
Working from a sincere interest in issues of social justice, William Boyce Thompson founded the Boyce Thompson Institute (BTI) in 1924, believing that basic plant research could lead to real societal benefit. BTI's fifteen faculty-run laboratories and greenhouse facilities are staffed by more than 110 researchers from more than forty countries. The research out of these laboratories has the potential to improve important food crops, demystify plant and human immune systems, and reveal alternative, sustainable sources of energy. Along with its research, BTI prioritizes environmental stewardship, and outreach to teachers, students, and community members.
The BTI has the mission to advance and communicate scientific knowledge in plant biology to improve agriculture, protect the environment, and enhance human health.
Contact
Reingard Grabherr
Austrian Centre of Industrial Biotechnology (acib) and BOKU Wien
reingard.grabherr@acib.at
Tel.: +43 1 47654 79006
Alexa Schmitz
Boyce Thompson Institute (BTI)
BTI Communications
bti_comm@cornell.edu
Tel.: +001 (607) 254-1234