Source: Okayama University (JAPAN), Public Relations and Information Strategy
For immediate release: 30 November 2017
Okayama University research: New method for suppressing lung cancer oncogene
(Okayama, 30 November) Researchers at Okayama University describe in Oncotarget an approach for suppressing the expression of the SOX2 protein, an oncogene associated with both lung and esophageal cancer. The procedure, based on the targeted delivery of a specially designed artificial protein, may signify an important step towards new cancer therapies.
Most cancer-related deaths world-wide are caused by lung cancer. For one type of lung cancer, lung squamous cell carcinoma (SCC), a protein called SOX2 is known to be a candidate oncogene - a gene that, under certain conditions, can transform a cell into a tumorous cell. A team of researchers led by Professor Takashi Sera from Okayama University has now found a method for suppressing SOX2 expression in cancer cells. The scientists’ approach involves a so-called artificial transcription factor (ATF) - a protein that regulates the production of a gene - and may lead to an effective therapy for not only lung SCC but also esophageal SCC.
The ATF created by Professor Sera and colleagues acting as a SOX2 suppressor is based on ‘zinc finger’ structures: protein motifs featuring stabilizing zinc ions. The researchers first showed that introduction of their ATF compound (labeled ATF/SOX2), consisting of 6 zinc-finger arrays, indeed leads to the suppression of SOX2 expression in vitro. They also confirmed that the ATF did not affect the viability of normal human cells. In a mouse model, ATF/SOX2 inhibited lung SCC tumor growth, confirming the effect of suppression of SOX2 in vivo.
Regarding the prospect of developing an SSC therapy based on ATF/SOX2, the scientists point out that an advantage of using ATFs is their small molecular weight, making it relatively easy to deliver them to target cells. They also note that ATFs can fuse with cell-penetrating peptides, providing a potential mechanism for the actual delivery. Moreover, this protein delivery approach is independent of cell type and there’s no risk of mutagenesis (a change in the genetic information of an organism).
Professor Sera and colleagues conclude that, although certain challenges still have to be overcome, “we have used ATF technology to successfully suppress SCC in vitro and in vivo … as a first step in the search for an effective treatment for SCC lung and esophageal cancers”.
Transcription factors are proteins that control how much genetic information is transcribed into messenger-RNA. Their function is to ensure that genes are synthesized (‘expressed’) at the right time and place in the cell, and in the right amount.
SOX2 is such a transcription factor; it plays an essential role in (early) mammalian development and in the maintenance of stem cells (cells that have the ability to differentiate - become cells of a specialized type).
In lung squamous cell carcinoma (SCC), SOX2 becomes overexpressed. Professor Takashi Sera from Okayama University and colleagues have now found an approach for suppressing SOX2 expression.
A zinc finger is a protein structural motif featuring one or more zinc ions. The zinc ions provide stabilization of the local folded protein structure by being a coordination center for surrounding ligands. Artificial transcription factors (ATFs) based on zinc-finger structures can be designed in such a way that they regulate the expression of particular target genes. Takashi Sera and colleagues have now shown that an ATF based on 6 zinc fingers can suppress the expression of SOX2, a protein identified as an oncogene for lung and esophageal squamous cell carcinoma (SCC).
Etsuko Yokota, Tomoki Yamatsuji, Munenori Takaoka, Minoru Haisa, Nagio Takigawa, Noriko Miyake, Tomoko Ikeda, Tomoaki Mori, Serika Ohno, Takashi Sera, Takuya Fukazawa & Yoshio Naomoto. Targeted silencing of SOX2 by an artificial transcription factor showed antitumor effect in lung and esophageal squamous cell carcinoma. Oncotarget, vol.8, No.61, pp.103063-103076, 2017.
Reference (Okayama Univ. e-Bulletin): Professor Sera’s team
・Prevention of RNA virus replication. (2016)
・Designer DNA-binding proteins to combat viral infections in agriculture and medicine. (2016)
・Immunizing plants: Creation of virus-resistant plants with artificial DNA-binding proteins. (2016)
・Okayama University at the Licensing Executives Society 2015 Annual Meeting in New York City. (2015)
・Selection as a Center for Excellence. (2014)
Professor Takashi Sera, Ph.D.
Department of Applied Chemistry and Biotechnology, Graduate
School of Natural Science and Technology, Okayama University,
3-1-1 Tsushimanaka, Kita-ku, Okayama 700-8530, Japan
e-mail : sera(a)cc.okayama-u.ac.jp
For inquiries, please contact us by replacing (a) with the @ mark.
1-1-1 Tsushima-naka , Kita-ku , Okayama 700-8530, Japan
Public Relations and Information Strategy
E-mail: www-adm (a) adm.okayama-u.ac.jp
For inquiries, please contact us by replacing (a) with the @ mark.
Okayama Univ. e-Bulletin: //www.okayama-u.ac.jp/user/kouhou/ebulletin/
About Okayama University (You Tube): https://www.youtube.com/watch?v=iDL1coqPRYIOkayama University Image Movie (You Tube): https://www.youtube.com/watch?v=KU3hOIXS5kk
Okayama University Medical Research Updates （OU-MRU）Vol.1：Innovative non-invasive ‘liquid biopsy’ method to capture circulating tumor cells from blood samples for genetic testingVol.2：Ensuring a cool recovery from cardiac arrestVol.3：Organ regeneration research leaps forwardVol.4：Cardiac mechanosensitive integratorVol.5：Cell injections get to the heart of congenital defectsVol.6：Fourth key molecule identified in bone developmentVol.7：Anticancer virus solution provides an alternative to surgeryVol.8：Light-responsive dye stimulates sight in genetically blind patientsVol.9：Diabetes drug helps towards immunity against cancerVol.10：Enzyme-inhibitors treat drug-resistant epilepsyVol.11：Compound-protein combination shows promise for arthritis treatmentVol.12：Molecular features of the circadian clock system in fruit fliesVol.13：Peptide directs artificial tissue growthVol.14：Simplified boron compound may treat brain tumoursVol.15：Metamaterial absorbers for infrared inspection technologiesVol.16：Epigenetics research traces how crickets restore lost limbsVol.17：Cell research shows pathway for suppressing hepatitis B virusVol.18：Therapeutic protein targets liver diseaseVol.19：Study links signalling protein to osteoarthritisVol.20：Lack of enzyme promotes fatty liver disease in thin patientsVol.21：Combined gene transduction and light therapy targets gastric cancerVol.22：Medical supportive device for hemodialysis catheter punctureVol.23：Development of low cost oral inactivated vaccines for dysenteryVol.24：Sticky molecules to tackle obesity and diabetesVol.25：Self-administered aroma foot massage may reduce symptoms of anxietyVol.26：Protein for preventing heart failureVol.27：Keeping cells in shape to fight sepsisVol.28：Viral-based therapy for bone cancerVol.29：Photoreactive compound allows protein synthesis control with lightVol.30：Cancer stem cells’ role in tumor growth revealedVol.31：Prevention of RNA virus replicationVol.32：Enzyme target for slowing bladder cancer invasionVol.33：Attacking tumors from the insideVol.34：Novel mouse model for studying pancreatic cancerVol.35：Potential cause of Lafora disease revealedVol.36：Overloading of protein localization triggers cellular defectsVol.37：Protein dosage compensation mechanism unravelledVol.38：Bioengineered tooth restoration in a large mammalVol.39：Successful test of retinal prosthesis implanted in ratsVol.40：Antibodies prolong seizure latency in epileptic miceVol.41：Inorganic biomaterials for soft-tissue adhesionVol.42：Potential drug for treating chronic pain with few side effectsVol.43：Potential origin of cancer-associated cells revealedVol.44：Protection from plant extractsVol.45：Link between biological-clock disturbance and brain dysfunction uncovered