|
Monday, 15 September 2014, 15:00 HKT/SGT | |
| | | | Source: A*STAR | |
|
|
|
A*STAR scientists have discovered genes in this tropical freshwater fish which may be synonymous with the genes for developing hair-like structures in the human airway |
SINGAPORE, Sept 15, 2014 - (ACN Newswire) - A small freshwater fish found in many tropical aquariums may hold the key to unlocking one of the leading causes of respiratory diseases in humans.
| A*STAR-Zebrafish |
Scientists from A*STAR's Institute of Molecular and Cell Biology (IMCB) have identified hundreds of novel genes in the zebrafish that could be functionally identical to the human genes required for forming motile cilia, hair-like structures on the surface of airway cells. These are required for removing dust and pathogens from the human airway. The study showed that the loss of these genes is linked to development of defective motile cilia, which could be the cause of some respiratory diseases.
Primary Ciliary Dyskinesia (PCD) is a rare genetic disorder which results in defective motile cilia within the human airway. Defective motile cilia cannot function properly to remove dust and bacteria from the lungs, leading to a range of respiratory problems, including chronic lung infections such as bronchitis and pneumonia, and in more severe cases, causes long term damage to the airway.
Reported recently as a cover article in Development, a leading research journal in developmental biology, the IMCB research team identified hundreds of novel genes that are associated with the development of motile cilia via genetic screening[1] in zebrafish. Out of nearly 600 genes found in the zebrafish, the researchers identified almost all of the 26 known genes responsible for PCD, implying that many more could be linked to the disorder.
Further studies on this discovery can yield useful information to pinpoint the genes associated with PCD. These genes may be valuable markers for the accurate diagnosis of PCD and other causes for defective motile cilia via genetic testing. This will in turn allow healthcare practitioners to implement mitigation strategies early.
"There is no cure for PCD. Doctors can only prescribe aggressive treatments to slow the progress of airway damage and address the respiratory issues resulting from PCD. It is therefore important to identify the genes responsible in a precise manner and diagnose the condition early," said Dr Sudipto Roy, Senior Principal Investigator at IMCB and the lead scientist for the study. "Our collection of genes will be invaluable for understanding how cilia are made and what cause them to be defective. They are important clues for understanding cilia-related diseases, and to develop future treatments," he added.
Professor Hong Wanjin, Executive Director of IMCB, said, "Developmental biology seeks to understand the basic principles governing the development of humans and how the emergence of complexities can be implicated in human diseases. This is exemplified in our study, which has uncovered the links between human diseases and the genes involved in cilia formation. Such foundational research is crucial as practical applications of research outcomes need to be grounded in fundamental science."
[1] Genetic screening is an experimental technique to identify unknown genes and to study gene function.
Notes to Editor: The research findings described in this media release can be found in the Development Journal, under the title, "Systematic discovery of novel ciliary genes through functional genomics in the zebrafish" by Semil P. Choksi,1, Deepak Babu,1,2, Doreen Lau,1, Xianwen Yu,1,*, and Sudipto Roy,1,2,3,4.
1. Institute of Molecular and Cell Biology, 61 Biopolis Drive, Singapore 138673; 2. NUS Graduate School of Integrative Sciences and Engineering, Centre for Life Sciences, 28 Medical Drive, Singapore 117456; 3. Department of Biological Sciences, National University of Singapore, 14 Science Drive 4, Singapore 117543; 4. Department of Paediatrics, Yong Loo Lin School of Medicine, National University of Singapore,1E Kent Ridge Road, Singapore 119288;
* Present address: Department of Biological Sciences, Key Laboratory of the Ministry of Education for Cell Biology and Tumor Cell Engineering, School of Life Sciences, Xiamen University, Xiamen, Fujian 361005, China.
Full text of the Development paper can be accessed online from: http://bit.ly/1uzd277
About the Institute of Molecular and Cell Biology (IMCB)
The Institute of Molecular and Cell Biology (IMCB) was launched on 23 January 1985, with its official opening ceremony held on 2 October 1987 at the National University of Singapore (NUS). It subsequently became an autonomous research institute (RI) of A*STAR, moving to Biopolis in 2004. IMCB's vision is to be a premier cell and molecular biology institute which addresses the mechanistic basis of human diseases and its mission is to conduct cutting-edge discovery research in disease pathways; to groom early career researchers to be future leaders in research; and to collaborate with medical and industry communities for research impact. IMCB plays an important role training and recruiting scientific talents, and has contributed to the development of other research entities in Singapore. Its success in fostering a biomedical research culture in Singapore has catalysed Singapore's transformation into an international hub for biomedical research, development and innovation.
Funded primarily by the Biomedical Research Council (BMRC) of A*STAR, IMCB's current discovery research includes cell biology in health and disease; animal models of development & disease; cancer & stem cell genetics & genomics; and structural biology & drug discovery. IMCB's translational research includes humanised model organisms for human diseases; systems approach for disease target identification & validation; and protein engineering & antibody development for diagnostics & therapeutics. Research activities in IMCB are supported by cutting edge infrastructure and facilities including quantitative proteomics; humanised mice; mouse models of human cancer; protein crystallography X-ray; zebrafish for drug metabolism & toxicology; advanced molecular histopathology; imaging & electron microscopy; and DNA sequencing. For more information about IMCB, visit www.imcb.a-star.edu.sg.
Contact:
Tan Yun Yun
Senior Officer, Corporate Communications
Agency for Science, Technology and Research
Tel: +65 6826 6273
Email: tan_yun_yun@a-star.edu.sg
Topic: Press release summary
Source: A*STAR
Sectors: Science & Research
http://www.acnnewswire.com
From the Asia Corporate News Network
Copyright © 2024 ACN Newswire. All rights reserved. A division of Asia Corporate News Network.
|
|
|
|
|
|
A*STAR |
Dec 6, 2022 14:00 HKT/SGT |
Global pharma giants partner Singapore researchers to boost innovation in biologics and vaccines manufacturing |
June 2, 2022 21:00 HKT/SGT |
Boehringer Ingelheim Enters Global Licensing Agreement to Develop and Commercialize Innovative Antibodies from A*STAR for Targeted Cancer Therapies |
June 2, 2022 21:00 HKT/SGT |
Boehringer Ingelheim Enters Global Licensing Agreement to Develop and Commercialize Innovative Antibodies from A*STAR for Targeted Cancer Therapies |
Sept 30, 2021 16:00 HKT/SGT |
A*STAR and Local SME Work with Vaccination Centres to Deploy AVID System for Filling Syringes |
July 31, 2020 08:00 HKT/SGT |
Singapore Cancer Drug ETC-159 Advances Further in Clinical Trials |
July 24, 2020 17:00 HKT/SGT |
MP Biomedicals and A*STAR Co-Develop Rapid Antibody Test Kit for SARS-CoV-2 |
Oct 22, 2019 04:00 HKT/SGT |
Fujitsu, SMU and A*STAR Launch Digital Platform Experimentation Project using Quantum-Inspired Computing and Deep Learning Technology |
June 28, 2019 08:00 HKT/SGT |
Singapore's Drug Development Efforts Given Additional Momentum with National Platforms |
Apr 5, 2019 18:00 HKT/SGT |
Passing of Dr Sydney Brenner, Nobel Laureate, Renowned Pioneer in Molecular Biology, A*Star Senior Fellow |
Jan 21, 2019 13:00 HKT/SGT |
Branched-Chain Amino Acids Found to Regulate the Development and Progression of Cancer |
More news >> |
|
|
|
|