What is the similarity between 'Yin and yang' switch, animal stem cells?
| Updated: Aug 23, 2017 11:20 IST
Washington D.C., Aug .10 (ANI): A study says that a molecular switch that flips between different versions of genes could be crucial for maintaining stem cells across all animals from simple flatworms to humans. The study at Center for Genomic Regulation says that flatworms (also known as planarians) have an incredible capacity for self-renewal, with almost any part of their body able to regenerate a whole new worm in a matter of days. The researchers found that they 'mix and match' certain parts of their genes in particular ways - a process known as alternative splicing. The same analysis of flatworm cells that had changed into more specific cell types revealed a different mixture of gene parts. Looking more closely, the team discovered that two families of molecules - CELF and MBNL - work as a kind of 'yin and yang' switch, enabling cells to flip between different patterns of alternative splicing. CELF molecules guide gene splicing patterns linked to self-renewal of stem cells, while MBNL factors favour differentiation. The study builds on Irimia's previous research showing that MBNL proteins and alternative splicing patterns are important in human and mouse embryonic stem cells as they differentiate into other cell types. Previously, scientists have discovered certain proteins, known as transcription factors that are important for maintaining embryonic stem cells in mammals. However, these particular molecules do not play the same roles in the stem cells of invertebrate organisms such as flatworms, which split off from the ancestors of mammals around 600 million years ago, suggesting that they are quite new in evolutionary terms. "Discovering that this kind of alternative splicing mechanism exists across such a wide evolutionary range suggests that it is very ancient, and may be equally important as transcription factors for giving animal stem cells their unique properties" said lead researcher Manuel Irimia. "Furthermore, understanding how this 'yin and yang' switch is flipped and activates particular patterns of alternative splicing could one day lead to more improved methods for generating and differentiating stem cells, which could be used be used for regenerative medicine," Irimia added. The study has been published in eLife. (ANI)