[News release] Activating genes on demand

In these images, the ability of the new Cas9 approach to differentiate stem cells into brain neuron cells is visible. On the left, a previous attempt to direct stem cells to develop into neuronal cells shows a low level of success, with limited red–colored areas indicating low growth of neuron cells. On the right, the new Cas9 approach shows a 40–fold increase in the number of neuronal cells developed, visible as red-colored areas on the image. Credit: Wyss Institute at Harvard University

 

From the 3 March 2015 Wyss Institute press release

New mechanism for engineering genetic traits governed by multiple genes paves the way for various advances in genomics and regenerative medicine 

When it comes to gene expression – the process by which our DNA provides the recipe used to direct the synthesis of proteins and other molecules that we need for development and survival – scientists have so far studied one single gene at a time. Anew approach developed by Harvard geneticist George Church, Ph.D., can help uncover how tandem gene circuits dictate life processes, such as the healthy development of tissue or the triggering of a particular disease, and can also be used for directing precision stem cell differentiation for regenerative medicine and growing organ transplants.

The findings, reported by Church and his team of researchers at the Wyss Institute for Biologically Inspired Engineering at Harvard University and Harvard Medical School in Nature Methods, show promise that precision gene therapies could be developed to prevent and treat disease on a highly customizable, personalized level, which is crucial given the fact that diseases develop among diverse pathways among genetically–varied individuals. Wyss Core Faculty member Jim Collins, Ph.D. was also a co-author on the paper. Collins is also the Henri Termeer Professor of Medical Engineering & Science and Professor in the Department of Biological Engineering at the Massachusetts Institute of Technology.

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March 10, 2015 Posted by Janice Flahiff | Medical and Health Research News | disease, disease causes, Gene expression, Massachusetts Institute of Technology, organ transplants, regenerative medicine, stem cells | Leave a comment

[Press release] Genome’s tale of ‘conquer and enslave’

From the 20 February 2015 University of Toronto press release

Toronto scientists uncovered how viral remnants helped shape control of our genes.

If genes were lights on a string of DNA, the genome would appear as an endless flicker, as thousands of genes come on and off at any given time. Tim Hughes, a Professor at the University of Toronto’s Donnelly Centre, is set on figuring out the rules behind this tightly orchestrated light-show, because when it fails, disease can occur.

Genes are switched on or off by proteins called transcription factors. These proteins bind to precise sites on the DNA that serve as guideposts, telling transcription factors that their target genes are nearby.

In their latest paper, published in Nature Biotechnology, Hughes and his team did the first systematic study of the largest group of human transcription factors, called C2H2-ZF.

Despite their important roles in development and disease, these proteins have been largely unexplored because they posed a formidable challenge for researchers.

C2H2-ZF transcription factors count over 700 proteins — around three per cent of all human genes! To make matters more complicated, most human C2H2-ZF proteins are very different from those in other organisms, like those in mice. This means that scientists could not apply insights gained from animal studies to human C2H2-ZFs.

Hughes’ team found something remarkable: the reason C2H2-ZFs are so abundant and diverse — which makes them difficult to study — is that many of them evolved to defend our ancestral genome from damage caused by the notorious “selfish DNA.”

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February 22, 2015 Posted by Janice Flahiff | Uncategorized | Gene expression, genetics, Transcription factor | Leave a comment