03:22pm Thursday 17 August 2017

Genetic discovery unlocks biosynthesis of medicinal compound in poppy

Poppies growing in Tasmania. Photo by Carol Walker

The discovery, published in the latest issue of Science, reveals that the pathway for synthesis of noscapine is controlled by a complex cluster of ten genes encoding five different enzyme classes. This is the most complex gene cluster ever found in plants. The discovery has revealed the previously unknown biochemical pathway for noscapine synthesis. It will also greatly accelerate the breeding of high-noscapine poppy varieties.

The breakthrough came when the scientists discovered that poppy varieties that produce noscapine express a number of genes that are absent in varieties that are noscapine free. They then analysed the inheritance pattern of these genes in hundreds of offspring from crosses between noscapine and no-noscapine varieties. When they saw that all of these genes are inherited together, they realised they could be looking at an incredibly complex gene cluster. The identity and arrangement of genes in the cluster was determined by cloning and DNA sequencing.

Professor Ian Graham, Director of the Centre for Novel Agricultural Products at the University of York, said: “We were amazed to find that this gene cluster encodes for almost the entire biosynthetic pathway for noscapine. With this one discovery we have been able to produce an outline of the pathway and define a number of the steps involved – something that normally takes years.”

We were amazed to find that this gene cluster encodes for almost the entire biosynthetic pathway for noscapine

Professor Ian Graham

Noscapine has been used as a suppressant in cough mixtures for decades. More recently, it has been reported to have anti-cancer activity and is currently in early stage clinical trials. Noscapine was one of the first natural products to be chemically characterised almost 200 years ago. Until now, however, the pathway for production and the genes involved in its synthesis have not been identified.

Tim Bowser, Head of R&D for GSK Australia’s Opiates Division, said: “The fact that the genes are grouped in a cluster means that plant breeding becomes faster and easier. GSK are using this discovery to develop high yielding commercial noscapine poppies in order to establish a reliable route of supply.”

Commercial poppy farming traditionally involved lancing the seed capsule to release the latex from which medicinal alkaloids, including noscapine, could be extracted. Since the 1960s commercial industrial techniques have largely switched to large scale poppy harvesting and extraction focussed on other medicinal poppy alkaloids like morphine and thebaine used to manufacture pain medicines. This trend has developed at the expense of noscapine which until now was only available from traditional techniques. 


Notes to editors:

  • “A Papaver somniferum ten gene cluster for synthesis of the anticancer alkaloid noscapine” by Thilo Winzer et al. will be published by Science within the Science Express web site (http://www.sciencemag.org/content/early/recent) on Thursday, 31 May 2012.  For a copy of the embargoed Science paper, contact the AAAS Office of Public Programs: tel +1-202-326-6440 or scipak@aaas.org.
  • Photographs to accompany this press release can be downloaded from http://www.york.ac.uk/news-and-events/news/2012/research/poppies/gallery. Explanatory text that can be used to accompany the images is as follows: “Tasmanian poppy fields. GSK Australia grow poppies commercially for the global pharmaceutical industry.”
  • The Centre for Novel Agricultural Products (CNAP) is an award winning strategic research centre based in the Biology Department at the University of York. CNAP is dedicated to realizing the potential of plants as renewable, low-cost factories that produce high-value chemicals and biofuels. Laboratory based discoveries are translated into practice in partnership with industry.
  • GlaxoSmithKline in Australia is one of the world’s leading producers of opiate-based raw materials, supplying around 20% of the global needs. The research collaboration with the University of York is targeted at improving the productivity of all useful opiate products including morphine, codeine and thebaine as well as noscapine, which is a non-opiate. GSK are developing high yielding noscapine poppies and have commenced the commercial production of noscapine from poppies as a new route of production.

Share on:

MORE FROM Genetics and Birth Defects

Health news