A team of researchers at the Broad Institute of Harvard and MIT has helped break new ground in stem cell research through work described in two recent
Nature papers. The most recently published study, appearing in the July 6 advance online issue, involves an effort to map regions of cells’ genomes marked by DNA methylation — one of several so-called ‘epigenetic’ modifications.
If DNA is the blueprint of a living organism, epigenetic marks, often in the form of chemical tags called methyl groups, are the gatekeepers to that blueprint. When affixed to DNA or to its protein scaffold (called “chromatin”), methyl groups can enable genes to be switched on or off, orchestrating signals that allow cells in the body, which share the same DNA, to assume different forms and functions.
In work published last year, Broad Institute researchers applied genomic tools to map the methylation of chromatin proteins called histones across the genomes of several types of cells, including embryonic stem cells. To complete that “epigenomic” picture, they decided to expand their work to include DNA methylation. “We used some of the latest genomic technologies,” said co-first author Alex Meissner, an assistant professor in Harvard's new Department of Stem Cell and Regenerative Biology, “to address a question many have wondered about: what’s the role of DNA methylation in cell development and differentiation?”
A long road towards DNA methylation maps
Researchers from the Whitehead Institute, Harvard University, and Harvard Medical School came together at the Broad Institute to analyze DNA methylation throughout the genomes of embryonic stem cells, as well as more developmentally mature cells.
Meissner said the new DNA methylation maps are the result of a long-term effort to address fundamental questions about how epigenetic factors influence cell development.
Researchers are able to create these maps using a technique known as bisulphite DNA sequencing. Although epigenetic information generally cannot be read from the As, Gs, Cs, and Ts that make up the DNA code, it turns out that a special chemical, sodium bisulphite, actually makes it possible to detect epigenetic modifications. Just as fine powders help detectives identify otherwise invisible fingerprints, sodium bisulphite helps scientists visualize the spots in a cell’s genome that harbor methyl groups and the spots that do not. The technique offers detailed views of DNA methylation and can now be implemented on a large-scale due to advances in high-throughput sequencing technologies.
With these advanced technologies, the scientists created DNA methylation maps of embryonic stem cells, as well as cell types derived from them, signifying the first such maps of mammalian cells. Several findings stood out from careful analyses of the maps, the most notable of which was the correlation between DNA methylation and histone methylation. Just as a topographic map of steep terrain and a political map of countries and borders may show similar patterns, chromatin and methylation maps can be used individually, or, more effectively, together to see a clearer picture of the molecular landscape. “In the past, these two types of epigenetic marks were rarely studied together,” said Tarjei Mikkelsen, a graduate student at the Broad Institute and co-first author of the latest Nature paper. “By examining them as a whole, we now have one of the first integrated pictures of epigenetic changes during cellular development.”
By perusing the maps, the researchers, led by Broad director Eric Lander, were also able to pick out specific sites within the genome where methylation fluctuates as cells develop, such as when embryonic stem cells mature into neural cells. Peering more closely at these dynamic changes, they identified certain sites associated with developmental genes that become overly methylated.
“Hypermethylation can be a sign that nearby genes are inaccessible, permanently shut off. And it is something that’s commonly observed in the genomes of tumor cells,” said Meissner. “These maps as well as the approaches used to create them may help shed light on the role of DNA methylation in human cancers.”
Increasing the efficiency of reprogramming
DNA methylation was also at the core of the scientists’ earlier paper, published in July 3 print issue of
Nature. That paper described several molecular hurdles that impede a powerful technique in stem cell research — a recently described laboratory procedure that can nudge adult cells into a more primitive, stem-cell like state. This cellular “reprogramming” is now the focus of intense interest as a potential way to artificially derive embryonic stem cells from readily available adult tissues, such as skin. The method, though, can be slow and inefficient, with most cells failing to be reprogrammed.
Epigenetic marks such as DNA methylation are thought to act like a kind of memory storage for cells, helping cells “remember” their identities by keeping certain genes turned off and others on. If that’s true, then reprogramming likely requires those memories to be reset or wiped clean, allowing cells to assume new identities. During the course of their research, the scientists discovered that some epigenetic information, particularly DNA methylation, is especially difficult to expunge, hindering the reprogramming process. They then showed that treating incompletely reprogrammed cells with a drug that temporarily inhibits DNA methylation could greatly increase the efficiency of the process.
“The same genes that are slow to respond to reprogramming are the genes we see hypermethylated early on in development,” Mikkelsen said “Improving the low efficiency of the reprogramming process required circumventing this mechanism without disabling it permanently.”
Having a map of these mechanisms could help researchers orient themselves in genomic space and develop additional methods to steer cells safely through the entire reprogramming process. Perhaps, like explorers before them, researchers today will also come across new discoveries along the way that will fill in more of the epigenetic maps.
Other Broad researchers who contributed to these papers include Eric Lander, Andreas Gnirke, Xiaolan Zhang, Bradley Bernstein, Andrey Sivachenko, Hongcang Gu, Chad Nusbaum, and David Jaffe. Researchers from the Whitehead Institute, Massachusetts General Hospital, and Harvard Medical School also contributed to the research.
Links:
http://www.nature.com/nature/journal/vaop/ncurrent/full/nature07107.html
Source: Harvard University
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