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Monday, 30 July 2012, 11:40 HKT/SGT | |
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SINGAPORE, July 30, 2012 - (ACN Newswire) - By studying fruit flies, scientists at A*STAR's Institute of Molecular and Cell Biology (IMCB) have successfully devised a fast and cost-saving way to uncover genetic changes that have a higher potential to cause cancer. With this new approach, researchers will now be able to rapidly distinguish the range of genetic changes that are causally linked to cancer (i.e. "driver" mutations) versus those with limited impact on cancer progression. This research paves the way for doctors to design more targeted treatment against the different cancer types, based on the specific cancer-linked mutations present in the patient. This study published in the prestigious journal Genes & Development could help advance the development of personalised medicine in cancer care and treatment.
| Fruit Flies Light the Way for A*STAR Scientists to Pinpoint Genetic Changes that Spell Cancer |
The era of genomic sequencing has generated an unparalleled wealth of information on the complexity of genetic changes that occur as cancer develops and progresses. "Many genetic changes arise in cancer cells and changes continue to accumulate during the progression of disease to metastatic cancer[1]. The current challenge is to understand which of the many genetic changes are important drivers of disease progression" said Dr. Stephen Cohen, Principal Investigator at IMCB and team leader of this paper.
Though very different in many ways, fruit flies and humans share similarities in a remarkable two-thirds of their genomes. That is to say, many of the genes found in humans are also present in the flies. Similarly, various signalling pathways involved in tumour formation are also well conserved from fruit flies to humans. In fact, previous studies have shown that about 75 percent of known human disease genes have a recognisable match in the genome of fruit flies[2].
Leveraging on their genetic similarities, Dr Hector Herranz, a post-doctorate from the Dr Cohen's team developed an innovative strategy to genetically screen the whole fly genome for "cooperating" cancer genes. On their own, these are the genes that appear to be harmless and have little or no impact on cancer. But in fact, they cooperate with other cancer genes, so that the combination causes aggressive cancer, which neither would cause alone.
In this study, the team was specifically looking for genes that could cooperate with EGFR[3] "driver" mutation, a genetic change commonly associated with breast and lung cancers in humans. SOCS5, reported in this paper, is one of the several new "cooperating" cancer genes to be identified through this innovative approach. Most of these new-found genes have yet to be identified as cancer genes in human or mouse models.
Said Mr Xin Hong, a PhD student and the co-first author of this paper, "We were very surprised by our finding because this it the first time that the Socs gene family is found to be linked to cancer. Previously it has only been associated with immunological disorders."
Dr. Cohen added, "Though these studies are in the early stages, they are very promising. Already, there are indications that levels of SOCS5 expression are reduced in breast cancer, and patients with low levels of SOCS5 have poor prognosis."
The IMCB team is preparing to explore the use of SOCS5 as a biomarker in diagnosis for cancer.
Said Professor Wanjin Hong, Executive Director of IMCB, "This study sheds light on the complexities of cancer genetics and paves the way to accelerate development of personalised medicine in cancer care. It is a fine examples of how powerful genetic approach using the fly model can reveal molecular mechanisms underlying human cancer. More importantly, it shows how fundamental research can have far-reaching applications for potential clinical benefits."
Notes for editor: The research findings described in this media release can be found in the 15 July 2012 issue of Genes & Developmentunder the title, "Oncogenic cooperation between SOCS family proteins and EGFR identified using a Drosophila epithelial transformation model" Hector Herranz[1,5], Xin Hong[1,2,5], Nguyen Thanh Hung[3], P. Mathijs Voorhoeve[3,4] and Stephen M. Cohen[1,2,6].
1. Institute of Molecular and Cell Biology, Singapore 138673, Singapore; 2. Department of Biological Sciences, National University of Singapore, Singapore 119613, Singapore; 3. Duke-NUS (National University of Singapore) Graduate Medical School, Singapore 169857, Singapore; 4. Department of Biochemistry, National University of Singapore, Singapore 119613, Singapore 5. These authors contributed equally to this work. 6. Corresponding author, E-mail: scohen@imcb.a-star.edu.sg Full text of this article can be accessed fromhttp://genesdev.cshlp.org/content/26/14/1602.full.pdf+html [1] Cancer metastasis is the rapid and often fatal spread of cancer cells from the primary tumour to other parts of the body, and is often the leading cause of death by cancer. [2] Reiter, LT; Potocki, L; Chien, S; Gribskov, M; Bier, E (2001). "A Systematic Analysis of Human Disease-Associated Gene Sequences In Drosophila melanogaster" Genome Research 11(6):1114-1125 http://www.ncbi.nlm.nih.gov/pmc/articles/PMC311089/?tool=pmcentrez [3] Epidermal growth factor receptor (EGFR) is a cell surface protein that binds epidermal growth factor binds, causing cells to divide. It is found at abnormally high levels on the surface of many types of cancer cells, so that these cancer cells may divide excessively in the presence of epidermal growth factor.
About Institute of Molecular and Cell Biology (IMCB)
The Institute of Molecular and Cell Biology (IMCB) is a member of Singapore's Agency for Science, Technology and Research (A*STAR) and is funded through A*STAR's Biomedical Research Council (BMRC). It is a world-class research institute that focuses its activities on six major fields: Cell Biology, Developmental Biology, Genomics, Structural Biology, Infectious Diseases, Cancer Biology and Translational Research, with core strengths in cell cycling, cell signalling, cell death, cell motility and protein trafficking. Its achievements include leading an international consortium that successfully sequenced the entire pufferfish (fugu) genome. The IMCB was awarded the Nikkei Prize 2000 for Technological Innovation in recognition of its growth into a leading international research centre and its collaboration with industry and research institutes worldwide. Established in 1987, the Institute currently has 26 independent research groups, eight core facilities and 300 researchers. For more information about IMCB, please visit www.imcb.a-star.edu.sg.
Contact:
Dr. Sarah Chang
Corporate Communications
Agency for Science, Technology and Research
Tel: +65 6826 6442
Email: chang_kai_chen@a-star.edu.sg
Topic: Research and development
Source: A*STAR
Sectors: Science & Research, BioTech
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