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Landmark study unlocks stem cell, DNA secrets to speed therapies
October 13, 2008In a groundbreaking study led by an eminent molecular biologist at Florida State University, researchers have discovered that as embryonic stem cells turn into different cell types, there are dramatic corresponding changes to the order in which DNA is replicated and reorganized.
The findings bridge a critical knowledge gap for stem cell biologists, enabling them to better understand the enormously complex process by which DNA is repackaged during differentiation -- when embryonic stem cells, jacks of all cellular trades, lose their anything-goes attitude and become masters of specialized functions.
As a result, scientists now are one significant step closer to the central goal of stem cell therapy, which is to successfully convert adult tissue back to an embryo-like state so that it can be used to regenerate or replace damaged tissue. Such therapies hold out hope of treatments or cures for cancer, Parkinson's disease, multiple sclerosis, spinal cord injuries and a host of other devastating disorders.
Using mouse and human embryonic stem cells, FSU researchers employed advanced imaging techniques and state-of-the-art genomics technology to demonstrate, with unprecedented resolution along long stretches of chromosomes, which sequences are replicated first, and which occur later in the process of differentiation.
"Understanding how replication works during embryonic stem cell differentiation gives us a molecular handle on how information is packaged in different types of cells in manners characteristic to each cell type," said David M. Gilbert, the study's principal investigator. "That handle will help us reverse the process in order to engineer different types of cells for use in disease therapies." Internationally renowned for his body of cutting-edge research on chromosomal structure and reproduction that he began as a doctoral student at Stanford University in the 1980's, Gilbert joined the FSU faculty and was appointed as the first J. Herbert Taylor Distinguished Professor of Molecular Biology in 2006.
Results from the FSU study, which includes contributions from researchers at three other institutions, are described in a paper published in the October 7, 2008, edition of PLoS Biology, a peer-reviewed journal that showcases biological science research of exceptional significance. So prodigious were the findings that the current paper -- "Global Reorganization of Replication Domains During Embryonic Stem Cell Differentiation" -- is focused solely on results observed in the mouse embryonic stems cells; data on the human cells will be detailed in a future report.
"We know that all the information (DNA) required to take on the identity of any tissue type is present in every cell, because we already can, albeit very inefficiently, create whole animals from adult
tissue through cloning," Gilbert said. "We also can make a kind of artificial embryonic stem cells, called induced pluripotent stem cells, out of many adult cell types, but there are two major hurdles remaining. First, the methods currently used rely on the unnatural retroviral insertion of genes into patients' cells, and these genes are capable of forming tumors. Second, this method is very inefficient as well because only one in 1,000 cells into which the genes are inserted becomes pluripotent. We must learn how cells lose pluripotency in the first place so we can do a better job of reversing the process without risks to patients.
"The challenge is, adult cells are highly specialized and over the course of their family history over many generations they've made decisions to be certain cell types rather than others," he said. "In doing so, they have tucked away the information they no longer need on how to become other cell types. Hence, all cells contain the same genetic information in their DNA, but during differentiation they package it with proteins into 'chromatin' in characteristic ways that define each cell type. The rules that determine how cells package DNA are complicated and have been difficult for scientists to decipher."
But, Gilbert noted, one time that the cell "shows its cards" is during DNA replication.
"During this process, which was the focus of our FSU research, it's not just the DNA that replicates," he said. "All the packaging must be replicated as well in each cell division cycle."
He explained that embryonic stem cells have many more, smaller "domains" of organization than differentiated cells, and it is during differentiation that they consolidate information.
"In fact, 'domain consolidation' is what we call the novel concept we discovered," he said.
Gilbert likened the concept of domain consolidation to the undeclared or "undifferentiated" college student who then consolidates her literature resources during the course of declaring a major and specialization. "From a student with books on all subjects on all of her bookshelves comes a student who has placed all texts pertaining to her major on the eye-level shelf and moved the distantly-related, potentially distracting texts to the hard-to-reach bottom or top shelves," he said.
"Now, our challenge as scientists," said Gilbert, "is to build on what we've learned about domain consolidation so that we can efficiently and safely create patient-specific induced pluripotent stem cells or even coax the body's cells to change their specialization in response to medications."
Florida State University
Using mouse and human embryonic stem cells, FSU researchers employed advanced imaging techniques and state-of-the-art genomics technology to demonstrate, with unprecedented resolution along long stretches of chromosomes, which sequences are replicated first, and which occur later in the process of differentiation.
"Understanding how replication works during embryonic stem cell differentiation gives us a molecular handle on how information is packaged in different types of cells in manners characteristic to each cell type," said David M. Gilbert, the study's principal investigator. "That handle will help us reverse the process in order to engineer different types of cells for use in disease therapies." Internationally renowned for his body of cutting-edge research on chromosomal structure and reproduction that he began as a doctoral student at Stanford University in the 1980's, Gilbert joined the FSU faculty and was appointed as the first J. Herbert Taylor Distinguished Professor of Molecular Biology in 2006.
Results from the FSU study, which includes contributions from researchers at three other institutions, are described in a paper published in the October 7, 2008, edition of PLoS Biology, a peer-reviewed journal that showcases biological science research of exceptional significance. So prodigious were the findings that the current paper -- "Global Reorganization of Replication Domains During Embryonic Stem Cell Differentiation" -- is focused solely on results observed in the mouse embryonic stems cells; data on the human cells will be detailed in a future report.
"We know that all the information (DNA) required to take on the identity of any tissue type is present in every cell, because we already can, albeit very inefficiently, create whole animals from adult
tissue through cloning," Gilbert said. "We also can make a kind of artificial embryonic stem cells, called induced pluripotent stem cells, out of many adult cell types, but there are two major hurdles remaining. First, the methods currently used rely on the unnatural retroviral insertion of genes into patients' cells, and these genes are capable of forming tumors. Second, this method is very inefficient as well because only one in 1,000 cells into which the genes are inserted becomes pluripotent. We must learn how cells lose pluripotency in the first place so we can do a better job of reversing the process without risks to patients.
"The challenge is, adult cells are highly specialized and over the course of their family history over many generations they've made decisions to be certain cell types rather than others," he said. "In doing so, they have tucked away the information they no longer need on how to become other cell types. Hence, all cells contain the same genetic information in their DNA, but during differentiation they package it with proteins into 'chromatin' in characteristic ways that define each cell type. The rules that determine how cells package DNA are complicated and have been difficult for scientists to decipher."
But, Gilbert noted, one time that the cell "shows its cards" is during DNA replication.
"During this process, which was the focus of our FSU research, it's not just the DNA that replicates," he said. "All the packaging must be replicated as well in each cell division cycle."
He explained that embryonic stem cells have many more, smaller "domains" of organization than differentiated cells, and it is during differentiation that they consolidate information.
"In fact, 'domain consolidation' is what we call the novel concept we discovered," he said.
Gilbert likened the concept of domain consolidation to the undeclared or "undifferentiated" college student who then consolidates her literature resources during the course of declaring a major and specialization. "From a student with books on all subjects on all of her bookshelves comes a student who has placed all texts pertaining to her major on the eye-level shelf and moved the distantly-related, potentially distracting texts to the hard-to-reach bottom or top shelves," he said.
"Now, our challenge as scientists," said Gilbert, "is to build on what we've learned about domain consolidation so that we can efficiently and safely create patient-specific induced pluripotent stem cells or even coax the body's cells to change their specialization in response to medications."
Florida State University
Embryonic Stem Cells Current Events and Embryonic Stem Cells News RSSTestes stem cell can change into other body tissues, Stanford/UCSF study shows
Scientists at the Stanford University School of Medicine and at UC-San Francisco have succeeded in isolating stem cells from human testes.
Patient-derived induced stem cells retain disease traits
hen neurons started dying in Clive Svendsen's lab dishes, he couldn't have been more pleased. The dying cells - the same type lost in patients with the devastating neurological disease spinal muscular atrophy - confirmed that the University of Wisconsin-Madison stem cell biologist had recreated the hallmarks of a genetic disorder in the lab, using stem cells derived from a patient.
Harm-reduction cigarettes are more toxic than traditional cigarettes, UC Riverside study finds
Typically, tobacco companies market harm-reduction cigarettes as being safer than traditional "full-flavored" brands, leading many smokers to conclude that the use of harm-reduction brands lowers their exposure to toxicants.
Model unravels rules that govern how genes are switched on and off
For years, scientists have struggled to decipher the genetic instruction book that details where and when the 20,000 genes in a human cell will be turned on or off. Different genes operate in each cell type at different times, and this careful orchestration is what ultimately distinguishes a brain cell from a liver or skin cell.
Pure insulin-producing cells produced in mouse
Singapore researchers have developed an unlimited number of pure insulin-producing cells from mouse embryonic stem cells (ESCs).
Washington University scientists first to sequence genome of cancer patient
For the first time, scientists have decoded the complete DNA of a cancer patient and traced her disease - acute myelogenous leukemia - to its genetic roots.
Stanford research sheds light on key trigger of embryonic stem cell differentiation
Clusters of mouse embryonic stem cells called embryoid bodies more closely approximate true embryos in organization and structure than previously thought, according to researchers at the Stanford University School of Medicine. Harnessing the signals that influence the cells' fate may help researchers more accurately direct the differentiation of embryonic stem cells for use in therapy.
Scripps research scientists identify compounds for stem-cell production from adult cells
In the study, the scientists screened known drugs and identified small molecules that could replace conventional reprogramming genes, which can have dangerous side effects.
Forsyth scientists trigger cancer-like response from embryonic stem cells
Scientists from The Forsyth Institute, working with collaborators at Tufts and Tuebingen Universities, have discovered a new control over embryonic stem cells' behavior.
A link between mitochondria and tumor formation in stem cells
Researchers report on a previously unknown relationship between stem cell potency and the metabolic rate of their mitochondria -a cell's energy makers. Stem cells with more active mitochondria also have a greater capacity to differentiate and are more likely to form tumors.
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