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How a single molecule turns one immune cell into another

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Posted August 1, 2015

Stills from time-lapse video showing transdifferentiation of pre-B cells into yeast-eating macrophages. Green fluorescent pre-B cells surrounded by red fluorescent Candida albicans at different hours after activation of C/EBPa (shown are same fields). Note that transdifferentiated macrophages in green aggregate while taking up the yeast, which now appear orange.

All it takes is one molecule to reprogram an antibody-producing B cell into a scavenging macrophage. This transformation is possible, new evidence shows, because the molecule (C/EBPa, a transcription factor) “short-circuits” the cells so that they re-express genes reserved for embryonic development. The findings appear July 30 inStem Cell Reports, the journal of the International Society for Stem Cell Research.

Over the past 28 years, researchers have shown that a number of specialized cell types can be forcibly converted into another, but the science of how this change takes place is still emerging. Such transdifferentiations, as they’re called, include turning a skin cell into a muscle cell (or a muscle cell into a brown fat cell) with the addition of just one or two transcription factors. These are molecules that bind to a cell’s DNA and cause other genes to be expressed.

“For a long time it was unclear whether forcing cell fate decisions by expressing transcription factors in the wrong cell type could teach us something about what happens normally during physiological differentiation,” says senior study author Thomas Graf of the Center for Genomic Regulation in Spain. “What we have now found is that the two processes are actually surprisingly similar.”

Based on experiments led by the first author of the study, Chris van Oevelen, B cell transdifferentiation takes place when C/EBPa binds to two regions of DNA that act as gene expression enhancers. Whereas one of these regions is normally active in immune cells, the other is only turned on when macrophage precursors are ready to differentiate. This indicates that the convergence of these two enhancer pathways can cause the B cell to act like a macrophage precursor, thus triggering the unnatural transdifferentiation.

“This has taught us a great deal about how a transcription factor can activate a new gene expression program (in our case, that of macrophages) but has left us in the dark about the other part of the equation; namely, how the factor silences the B cell program, something that must happen if transdifferentiation is to work,” Graf says. “This is one of the questions we are focusing on now.”

Graf is interested in this pathway because C/EBPa-induced, B cell-to-macrophage transdifferentiation can convert both human B cell lymphoma or leukaemia cells into functional, non-cancerous macrophages. He believes that induced transdifferentiation could become therapeutically relevant, if a drug could be found that can replace the transcription factor–not to mention that understanding the mechanisms of the process would help labs worldwide who use this transdifferentiation approach to generate cells “a la carte” for regenerative purposes.

Source: EurekAlert

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