Archive for the ‘IPS Cell Therapy’ Category
Study demonstrates cells can acquire new functions through transcriptional regulatory network
Starting with the first-ever production of induced pluripotent stem cells (iPS cells) in 2006, cell reprogramming - the genetic conversion of cells from one type to another - has revolutionized stem cell research and opened the door to countless new medical applications. Inducing such reprogramming, however, is difficult, inefficient and time-consuming, involving a largely hit-or-miss process of selecting candidate genes.
In the current study, the OSC research team explored an alternative to iPS cells based on the use of transcriptional regulatory networks (TRNs), networks of transcription factors and the genes they regulate. Previous research by the team characterized the dynamic regulatory activities of such transcription factors during cellular differentiation from immature cell (monoblast) to developed (monocyte-like) cell using human acute monocytic leukemia cell lines (THP-1). Their findings led them to hypothesize that functional characteristics of the cell-type are maintained by its specific TRN.
Their new paper builds on this hypothesis, establishing a series of new methods for identifying transcription factors (TFs) for the monocyte network, which play a key role in inducing cell-specific functions. Four core TF genes of the monocyte TRN, identified using this approach, were introduced into human fibroblast cells, expression of which activated monocytic functions including phagocytosis, inflammatory response and chemotaxis. Genome-wide gene expression analysis of this reprogrammed cell showed monocyte-like gene expression profile, demonstrating that reconstruction of a functional TRN can be achieved by introducing core TRN elements into unrelated cell types.
Published in the journal PLoS ONE, the newly-developed methods open the door to a new form of direct cell reprogramming for clinical use which avoids the pitfalls of embryonic stem (ES) and induced pluripotent stem (iPS) cells, charting a course toward novel applications in regenerative medicine and drug discovery.
Provided by RIKEN (news : web)
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Study demonstrates cells can acquire new functions through transcriptional regulatory network
Gut Cells Turned To Insulin Factories – New Type l Diabetes Treatment
Editor's Choice Academic Journal Main Category: Diabetes Article Date: 13 Mar 2012 - 12:00 PDT
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The study was carried out by Chutima Talchai, Ph.D, a New York Stem Cell Foundation-Druckenmiller Fellow, and Domenico Accili, M.D., professor of medicine at Columbia University Medical Center.
Type 1 diabetes is an autoimmune disease that kills cells in the pancreas which produce insulin, resulting in high levels of glucose in the blood. As the pancreas is unable to replace these cells, individuals suffering with the disease must inject insulin into themselves in order to manage their blood sugar. Patients must also monitor their sugar levels numerous times a day, as blood glucose that is too low or too high can be fatal.
For scientists researching type 1 diabetes, one of the leading goals is to replace lost insulin-producing cells with new cells that release insulin into the bloodstream as needed. Even though researchers are able to generate these cells in the laboratory from embryonic stem cells, they are not suitable for transplant in patients as they do not release insulin appropriately in response to sugar levels, potentially resulting in a deadly condition called hypoglycemia.
In the intestine of mice, the researchers found that certain gastrointestinal progenitor cells are able to generate insulin-producing cells.
Usually, progenitor cells are responsible for generating a vast range of cells, such as gastric inhibitory peptide, cells that produce serotonin, as well as other hormones secreted into the GI tract and bloodstream.
The researchers discovered that when they switched off Foxo1 (a gene known to contribute in cell fate decisions), the progenitor cells also generated cells that produced insulin. In addition, the team found that although more cells were produced when Foxo1 was switched off early in development, they were also produced when the Foxo1 was switched off in adult mice.
Dr. Accili, explained:
Originally posted here:
Gut Cells Turned To Insulin Factories - New Type l Diabetes Treatment
Gut Cells Turned To Insulin Factories – New Type l Diabetes Treatment
Editor's Choice Academic Journal Main Category: Diabetes Article Date: 13 Mar 2012 - 12:00 PDT
email to a friend printer friendly opinions
Current Article Ratings:
The study was carried out by Chutima Talchai, Ph.D, a New York Stem Cell Foundation-Druckenmiller Fellow, and Domenico Accili, M.D., professor of medicine at Columbia University Medical Center.
Type 1 diabetes is an autoimmune disease that kills cells in the pancreas which produce insulin, resulting in high levels of glucose in the blood. As the pancreas is unable to replace these cells, individuals suffering with the disease must inject insulin into themselves in order to manage their blood sugar. Patients must also monitor their sugar levels numerous times a day, as blood glucose that is too low or too high can be fatal.
For scientists researching type 1 diabetes, one of the leading goals is to replace lost insulin-producing cells with new cells that release insulin into the bloodstream as needed. Even though researchers are able to generate these cells in the laboratory from embryonic stem cells, they are not suitable for transplant in patients as they do not release insulin appropriately in response to sugar levels, potentially resulting in a deadly condition called hypoglycemia.
In the intestine of mice, the researchers found that certain gastrointestinal progenitor cells are able to generate insulin-producing cells.
Usually, progenitor cells are responsible for generating a vast range of cells, such as gastric inhibitory peptide, cells that produce serotonin, as well as other hormones secreted into the GI tract and bloodstream.
The researchers discovered that when they switched off Foxo1 (a gene known to contribute in cell fate decisions), the progenitor cells also generated cells that produced insulin. In addition, the team found that although more cells were produced when Foxo1 was switched off early in development, they were also produced when the Foxo1 was switched off in adult mice.
Dr. Accili, explained:
Here is the original post:
Gut Cells Turned To Insulin Factories - New Type l Diabetes Treatment
Columbia Researchers Find Potential Role for Gut Cells in Treating Type I Diabetes
Published: March 12, 2012
(NEW YORK, NY, March 11, 2012) A study by Columbia researchers suggests that cells in the patients intestine could be coaxed into making insulin, circumventing the need for a stem cell transplant. Until now, stem cell transplants have been seen by many researchers as the ideal way to replace cells lost in type I diabetes and to free patients from insulin injections.
The researchconducted in micewas published 11 March 2012 in the journal Nature Genetics.
Type I diabetes is an autoimmune disease that destroys insulin-producing cells in the pancreas. The pancreas cannot replace these cells, so once they are lost, people with type I diabetes must inject themselves with insulin to control their blood glucose. Blood glucose that is too high or too low can be life threatening, and patients must monitor their glucose several times a day.
Gut insulin cells express glucokinase, a key enzyme for glucose processing. Immunostaining detected insulin in red and glucokinase in green. Yellow marked merged colors.
A longstanding goal of type I diabetes research is to replace lost cells with new cells that release insulin into the bloodstream as needed. Though researchers can make insulin-producing cells in the laboratory from embryonic stem cells, such cells are not yet appropriate for transplant because they do not release insulin appropriately in response to glucose levels. If these cells were introduced into a patient, insulin would be secreted when not needed, potentially causing fatal hypoglycemia.
The study, conducted by Chutima Talchai, PhD, and Domenico Accili, MD, professor of medicine at Columbia University Medical Center, shows that certain progenitor cells in the intestine of mice have the surprising ability to make insulin-producing cells. Dr. Talchai, who works in Dr. Accilis lab, is a New York Stem Cell Foundation-Druckenmiller Fellow.
The gastrointestinal progenitor cells are normally responsible for producing a wide range of cells, including cells that produce serotonin, gastric inhibitory peptide, and other hormones secreted into the GI tract and bloodstream.
Inactivation of Foxo1, a gene important for metabolism generated insulin producing cells in small intestines of newborn mice, as detected by immunofluorescence in red.Drs. Talchai and Accili found that when they turned off a gene known to play a role in cell fate decisionsFoxo1the progenitor cells also generated insulin-producing cells. More cells were generated when Foxo1 was turned off early in development, but insulin-producing cells were also generated when the gene was turned off after the mice had reached adulthood.
Our results show that it could be possible to regrow insulin-producing cells in the GI tracts of our pediatric and adult patients, Dr. Accili says.
See the original post here:
Columbia Researchers Find Potential Role for Gut Cells in Treating Type I Diabetes
Gut cells transformed into insulin factories 'could help to treat type I diabetes'
London, Mar 12 (ANI): A new study conducted by scientists suggests a new approach that could give patients the ability to make their own insulin-producing cells without a stem cell transplant.
Until now, stem cell transplants have been seen by many researchers as the ideal way to replace cells lost in type I diabetes and to free patients from insulin injections.
Type I diabetes is an autoimmune disease that destroys insulin-producing cells in the pancreas. The pancreas cannot replace these cells, so once they are lost, people with type I diabetes must inject themselves with insulin to control their blood glucose.
Blood glucose that is too high or too low can be life threatening, and patients must monitor their glucose several times a day.
A longstanding goal of type I diabetes research is to replace lost cells with new cells that release insulin into the bloodstream as needed.
Though researchers can make insulin-producing cells in the laboratory from embryonic stem cells, such cells are not yet appropriate for transplant because they do not release insulin appropriately in response to glucose levels.
If these cells were introduced into a patient, insulin would be secreted when not needed, potentially causing fatal hypoglycemia.
The study, conducted by Chutima Talchai and Domenico Accili from Columbia University Medical Center, shows that certain progenitor cells in the intestine of mice have the surprising ability to make insulin-producing cells.
The gastrointestinal progenitor cells are normally responsible for producing a wide range of cells, including cells that produce serotonin, gastric inhibitory peptide, and other hormones secreted into the GI tract and bloodstream.
They found that when they turned off a gene known to play a role in cell fate decisions-Foxo1-the progenitor cells also generated insulin-producing cells. More cells were generated when Foxo1 was turned off early in development, but insulin-producing cells were also generated when the gene was turned off after the mice had reached adulthood.
Original post:
Gut cells transformed into insulin factories 'could help to treat type I diabetes'
Columbia Researchers Find Potential Role for Gut Cells in Treating Type I Diabetes
Published: March 12, 2012
(NEW YORK, NY, March 11, 2012) A study by Columbia researchers suggests that cells in the patients intestine could be coaxed into making insulin, circumventing the need for a stem cell transplant. Until now, stem cell transplants have been seen by many researchers as the ideal way to replace cells lost in type I diabetes and to free patients from insulin injections.
The researchconducted in micewas published 11 March 2012 in the journal Nature Genetics.
Type I diabetes is an autoimmune disease that destroys insulin-producing cells in the pancreas. The pancreas cannot replace these cells, so once they are lost, people with type I diabetes must inject themselves with insulin to control their blood glucose. Blood glucose that is too high or too low can be life threatening, and patients must monitor their glucose several times a day.
Gut insulin cells express glucokinase, a key enzyme for glucose processing. Immunostaining detected insulin in red and glucokinase in green. Yellow marked merged colors.
A longstanding goal of type I diabetes research is to replace lost cells with new cells that release insulin into the bloodstream as needed. Though researchers can make insulin-producing cells in the laboratory from embryonic stem cells, such cells are not yet appropriate for transplant because they do not release insulin appropriately in response to glucose levels. If these cells were introduced into a patient, insulin would be secreted when not needed, potentially causing fatal hypoglycemia.
The study, conducted by Chutima Talchai, PhD, and Domenico Accili, MD, professor of medicine at Columbia University Medical Center, shows that certain progenitor cells in the intestine of mice have the surprising ability to make insulin-producing cells. Dr. Talchai, who works in Dr. Accilis lab, is a New York Stem Cell Foundation-Druckenmiller Fellow.
The gastrointestinal progenitor cells are normally responsible for producing a wide range of cells, including cells that produce serotonin, gastric inhibitory peptide, and other hormones secreted into the GI tract and bloodstream.
Inactivation of Foxo1, a gene important for metabolism generated insulin producing cells in small intestines of newborn mice, as detected by immunofluorescence in red.Drs. Talchai and Accili found that when they turned off a gene known to play a role in cell fate decisionsFoxo1the progenitor cells also generated insulin-producing cells. More cells were generated when Foxo1 was turned off early in development, but insulin-producing cells were also generated when the gene was turned off after the mice had reached adulthood.
Our results show that it could be possible to regrow insulin-producing cells in the GI tracts of our pediatric and adult patients, Dr. Accili says.
View original post here:
Columbia Researchers Find Potential Role for Gut Cells in Treating Type I Diabetes
Gut cells transformed into insulin factories 'could help to treat type I diabetes'
London, Mar 12 (ANI): A new study conducted by scientists suggests a new approach that could give patients the ability to make their own insulin-producing cells without a stem cell transplant.
Until now, stem cell transplants have been seen by many researchers as the ideal way to replace cells lost in type I diabetes and to free patients from insulin injections.
Type I diabetes is an autoimmune disease that destroys insulin-producing cells in the pancreas. The pancreas cannot replace these cells, so once they are lost, people with type I diabetes must inject themselves with insulin to control their blood glucose.
Blood glucose that is too high or too low can be life threatening, and patients must monitor their glucose several times a day.
A longstanding goal of type I diabetes research is to replace lost cells with new cells that release insulin into the bloodstream as needed.
Though researchers can make insulin-producing cells in the laboratory from embryonic stem cells, such cells are not yet appropriate for transplant because they do not release insulin appropriately in response to glucose levels.
If these cells were introduced into a patient, insulin would be secreted when not needed, potentially causing fatal hypoglycemia.
The study, conducted by Chutima Talchai and Domenico Accili from Columbia University Medical Center, shows that certain progenitor cells in the intestine of mice have the surprising ability to make insulin-producing cells.
The gastrointestinal progenitor cells are normally responsible for producing a wide range of cells, including cells that produce serotonin, gastric inhibitory peptide, and other hormones secreted into the GI tract and bloodstream.
They found that when they turned off a gene known to play a role in cell fate decisions-Foxo1-the progenitor cells also generated insulin-producing cells. More cells were generated when Foxo1 was turned off early in development, but insulin-producing cells were also generated when the gene was turned off after the mice had reached adulthood.
Read the original:
Gut cells transformed into insulin factories 'could help to treat type I diabetes'
A new approach to treating type I diabetes? Gut cells transformed into insulin factories
Public release date: 11-Mar-2012 [ | E-mail | Share ]
Contact: Karin Eskenazi ket2116@columbia.edu 212-342-0508 Columbia University Medical Center
NEW YORK, NY -- A study by Columbia researchers suggests that cells in the patient's intestine could be coaxed into making insulin, circumventing the need for a stem cell transplant. Until now, stem cell transplants have been seen by many researchers as the ideal way to replace cells lost in type I diabetes and to free patients from insulin injections.
The researchconducted in micewas published 11 March 2012 in the journal Nature Genetics.
Type I diabetes is an autoimmune disease that destroys insulin-producing cells in the pancreas. The pancreas cannot replace these cells, so once they are lost, people with type I diabetes must inject themselves with insulin to control their blood glucose. Blood glucose that is too high or too low can be life threatening, and patients must monitor their glucose several times a day.
A longstanding goal of type I diabetes research is to replace lost cells with new cells that release insulin into the bloodstream as needed. Though researchers can make insulin-producing cells in the laboratory from embryonic stem cells, such cells are not yet appropriate for transplant because they do not release insulin appropriately in response to glucose levels. If these cells were introduced into a patient, insulin would be secreted when not needed, potentially causing fatal hypoglycemia.
The study, conducted by Chutima Talchai, PhD, and Domenico Accili, MD, professor of medicine at Columbia University Medical Center, shows that certain progenitor cells in the intestine of mice have the surprising ability to make insulin-producing cells. Dr. Talchai is a postdoctoral fellow in Dr. Accili's lab.
The gastrointestinal progenitor cells are normally responsible for producing a wide range of cells, including cells that produce serotonin, gastric inhibitory peptide, and other hormones secreted into the GI tract and bloodstream.
Drs. Talchai and Accili found that when they turned off a gene known to play a role in cell fate decisionsFoxo1the progenitor cells also generated insulin-producing cells. More cells were generated when Foxo1 was turned off early in development, but insulin-producing cells were also generated when the gene was turned off after the mice had reached adulthood.
"Our results show that it could be possible to regrow insulin-producing cells in the GI tracts of our pediatric and adult patients," Dr. Accili says.
View post:
A new approach to treating type I diabetes? Gut cells transformed into insulin factories
New approach to treating type 1 diabetes? Transforming gut cells into insulin factories
ScienceDaily (Mar. 11, 2012) A study by Columbia researchers suggests that cells in the patient's intestine could be coaxed into making insulin, circumventing the need for a stem cell transplant. Until now, stem cell transplants have been seen by many researchers as the ideal way to replace cells lost in type I diabetes and to free patients from insulin injections.
The research -- conducted in mice -- was published 11 March 2012 in the journal Nature Genetics.
Type I diabetes is an autoimmune disease that destroys insulin-producing cells in the pancreas. The pancreas cannot replace these cells, so once they are lost, people with type I diabetes must inject themselves with insulin to control their blood glucose. Blood glucose that is too high or too low can be life threatening, and patients must monitor their glucose several times a day.
A longstanding goal of type I diabetes research is to replace lost cells with new cells that release insulin into the bloodstream as needed. Though researchers can make insulin-producing cells in the laboratory from embryonic stem cells, such cells are not yet appropriate for transplant because they do not release insulin appropriately in response to glucose levels. If these cells were introduced into a patient, insulin would be secreted when not needed, potentially causing fatal hypoglycemia.
The study, conducted by Chutima Talchai, PhD, and Domenico Accili, MD, professor of medicine at Columbia University Medical Center, shows that certain progenitor cells in the intestine of mice have the surprising ability to make insulin-producing cells. Dr. Talchai is a postdoctoral fellow in Dr. Accili's lab.
The gastrointestinal progenitor cells are normally responsible for producing a wide range of cells, including cells that produce serotonin, gastric inhibitory peptide, and other hormones secreted into the GI tract and bloodstream.
Drs. Talchai and Accili found that when they turned off a gene known to play a role in cell fate decisions -- Foxo1 -- the progenitor cells also generated insulin-producing cells. More cells were generated when Foxo1 was turned off early in development, but insulin-producing cells were also generated when the gene was turned off after the mice had reached adulthood. "Our results show that it could be possible to regrow insulin-producing cells in the GI tracts of our pediatric and adult patients," Dr. Accili says.
"Nobody would have predicted this result," Dr. Accili adds. "Many things could have happened after we knocked out Foxo1. In the pancreas, when we knock out Foxo1, nothing happens. So why does something happen in the gut? Why don't we get a cell that produces some other hormone? We don't yet know."
Insulin-producing cells in the gut would be hazardous if they did not release insulin in response to blood glucose levels. But the researchers say that the new intestinal cells have glucose-sensing receptors and do exactly that.
The insulin made by the gut cells also was released into the bloodstream, worked as well as normal insulin, and was made in sufficient quantity to nearly normalize blood glucose levels in otherwise diabetic mice.
More:
New approach to treating type 1 diabetes? Transforming gut cells into insulin factories
New approach to treating type 1 diabetes? Transforming gut cells into insulin factories
ScienceDaily (Mar. 11, 2012) A study by Columbia researchers suggests that cells in the patient's intestine could be coaxed into making insulin, circumventing the need for a stem cell transplant. Until now, stem cell transplants have been seen by many researchers as the ideal way to replace cells lost in type I diabetes and to free patients from insulin injections.
The research -- conducted in mice -- was published 11 March 2012 in the journal Nature Genetics.
Type I diabetes is an autoimmune disease that destroys insulin-producing cells in the pancreas. The pancreas cannot replace these cells, so once they are lost, people with type I diabetes must inject themselves with insulin to control their blood glucose. Blood glucose that is too high or too low can be life threatening, and patients must monitor their glucose several times a day.
A longstanding goal of type I diabetes research is to replace lost cells with new cells that release insulin into the bloodstream as needed. Though researchers can make insulin-producing cells in the laboratory from embryonic stem cells, such cells are not yet appropriate for transplant because they do not release insulin appropriately in response to glucose levels. If these cells were introduced into a patient, insulin would be secreted when not needed, potentially causing fatal hypoglycemia.
The study, conducted by Chutima Talchai, PhD, and Domenico Accili, MD, professor of medicine at Columbia University Medical Center, shows that certain progenitor cells in the intestine of mice have the surprising ability to make insulin-producing cells. Dr. Talchai is a postdoctoral fellow in Dr. Accili's lab.
The gastrointestinal progenitor cells are normally responsible for producing a wide range of cells, including cells that produce serotonin, gastric inhibitory peptide, and other hormones secreted into the GI tract and bloodstream.
Drs. Talchai and Accili found that when they turned off a gene known to play a role in cell fate decisions -- Foxo1 -- the progenitor cells also generated insulin-producing cells. More cells were generated when Foxo1 was turned off early in development, but insulin-producing cells were also generated when the gene was turned off after the mice had reached adulthood. "Our results show that it could be possible to regrow insulin-producing cells in the GI tracts of our pediatric and adult patients," Dr. Accili says.
"Nobody would have predicted this result," Dr. Accili adds. "Many things could have happened after we knocked out Foxo1. In the pancreas, when we knock out Foxo1, nothing happens. So why does something happen in the gut? Why don't we get a cell that produces some other hormone? We don't yet know."
Insulin-producing cells in the gut would be hazardous if they did not release insulin in response to blood glucose levels. But the researchers say that the new intestinal cells have glucose-sensing receptors and do exactly that.
The insulin made by the gut cells also was released into the bloodstream, worked as well as normal insulin, and was made in sufficient quantity to nearly normalize blood glucose levels in otherwise diabetic mice.
See original here:
New approach to treating type 1 diabetes? Transforming gut cells into insulin factories
A new approach to treating type I diabetes? Gut cells transformed into insulin factories
Public release date: 11-Mar-2012 [ | E-mail | Share ]
Contact: Karin Eskenazi ket2116@columbia.edu 212-342-0508 Columbia University Medical Center
NEW YORK, NY -- A study by Columbia researchers suggests that cells in the patient's intestine could be coaxed into making insulin, circumventing the need for a stem cell transplant. Until now, stem cell transplants have been seen by many researchers as the ideal way to replace cells lost in type I diabetes and to free patients from insulin injections.
The researchconducted in micewas published 11 March 2012 in the journal Nature Genetics.
Type I diabetes is an autoimmune disease that destroys insulin-producing cells in the pancreas. The pancreas cannot replace these cells, so once they are lost, people with type I diabetes must inject themselves with insulin to control their blood glucose. Blood glucose that is too high or too low can be life threatening, and patients must monitor their glucose several times a day.
A longstanding goal of type I diabetes research is to replace lost cells with new cells that release insulin into the bloodstream as needed. Though researchers can make insulin-producing cells in the laboratory from embryonic stem cells, such cells are not yet appropriate for transplant because they do not release insulin appropriately in response to glucose levels. If these cells were introduced into a patient, insulin would be secreted when not needed, potentially causing fatal hypoglycemia.
The study, conducted by Chutima Talchai, PhD, and Domenico Accili, MD, professor of medicine at Columbia University Medical Center, shows that certain progenitor cells in the intestine of mice have the surprising ability to make insulin-producing cells. Dr. Talchai is a postdoctoral fellow in Dr. Accili's lab.
The gastrointestinal progenitor cells are normally responsible for producing a wide range of cells, including cells that produce serotonin, gastric inhibitory peptide, and other hormones secreted into the GI tract and bloodstream.
Drs. Talchai and Accili found that when they turned off a gene known to play a role in cell fate decisionsFoxo1the progenitor cells also generated insulin-producing cells. More cells were generated when Foxo1 was turned off early in development, but insulin-producing cells were also generated when the gene was turned off after the mice had reached adulthood.
"Our results show that it could be possible to regrow insulin-producing cells in the GI tracts of our pediatric and adult patients," Dr. Accili says.
Read the original here:
A new approach to treating type I diabetes? Gut cells transformed into insulin factories
Presentations at the Society of Toxicology Annual Meeting Demonstrate Superior Predictivity of Cellular Dynamics …
MADISON, Wis., March 8, 2012 /PRNewswire/ --Cellular Dynamics International, Inc. (CDI), the world's largest commercial producer of human induced pluripotent stem (iPS) cell lines and tissue cells for drug discovery and safety, today announced several customer presentations of studies employing the company's iCell products at the Society of Toxicology (SOT) Annual Meeting on March 11 to 15 in San Francisco. A number of these studies demonstrate the superior predictivity of CDI's human iPS cell-derived products compared to other cell models, such as animal models and immortalized cell lines, which are historically used in pharmaceutical drug discovery and toxicity testing.
Customers will present 11 abstracts employing CDI's human cells in their research during the SOT meeting. Several of these compare the superior ability of CDI's iCell Cardiomyocytes and iCell Hepatocytes to predict toxic responses to currently available cell models. Among them:
Puppala, D et al. (Abstract 420 Poster Board -642; Pfizer, Inc.) compared the ability of iCell Cardiomyocytes to a rat cardiac-derived cell line (H9C2) to predict the toxicity of 10 known in vivo cardiac toxins that were not flagged by the company's current in vitro assay systems. They found that iCell Cardiomyocytes showed increases in several toxicity signals and were more accurate in detecting cardiotoxicity than the rat cell line.
Guo, L et al. (Abstract 1168 Poster Board -433; Hoffman-La Roche) utilized sets of reference and internal compounds to determine the accuracy with which iCell Cardiomyocytes can predict arrhythmic effects. Based on drug-induced changes in beating pattern, iCell Cardiomyocytes correctly identified 17 of 19 reference compounds known to cause abnormal ECG patterns in humans and 17 of 17 internal compounds known to cause arrhythmia in non-rodent animals. These results demonstrate the predictive value of utilizing iCell Cardiomyocytes to identify proarrhythmic compounds.
Hong, S et al. (Abstract 1149 Poster Board -414; Bristol-Myers Squibb) evaluated the effects of three drug compounds using both iCell Cardiomyocytes and fetal rat cardiomyocytes utilizing multi-electrode array (MEA) assays. For all three compounds, iCell Cardiomyocytes were better suited than the fetal rat cardiomyocytes at predicting adverse in vivo effects, including those effects that were not discovered until small-scale clinical trials.
Kameoka, S et al. (Abstract 519 Poster Board -237; Hoffman-La Roche) compared the toxicity of three drug candidates previously tested on dog hepatocytes to iCell Hepatocytes and primary human hepatocytes. In dogs, two of the three compounds caused liver toxicity. The profiles of the two toxic compounds were almost identically recapitulated in vitro for both the primary human hepatocytes and iCell Hepatocytes. This study demonstrated that iCell Hepatocytes may be a valuable human model to predict hepatic toxicity in vitro.
Additional SOT presentations employing CDI's iCell products can be found on the SOT Annual Meeting website or at http://www.cellulardynamics.com/sot2012/posters.html.
"These studies are important contributors to the collective understanding that human in vitro cellular model systems are superior to animal models and immortalized cell lines when studying questions of human biology," said Chris Parker, chief commercial officer of CDI. "We recognize that iPS cell-derived tissues are a relatively new model for drug discovery and toxicity testing and must be validated and shown to be superior. It is gratifying that our pharmaceutical customers are presenting data validating the performance characteristics of our heart and liver cells in such an open scientific forum as the Society of Toxicology Annual Meeting. Third-party validation of iCell product performance coupled with CDI's proven ability to deliver human cells in the quantity, quality and purity required for pharmaceutical, biomedical and basic research positions us well for supplying customers with the human cells they need to improve healthcare."
About Cellular Dynamics International, Inc.Cellular Dynamics International, Inc. (CDI) is a leading developer of next-generation stem cell technologies for drug development, cell therapy, tissue engineering and organ regeneration. CDI harnesses its unique manufacturing technology to produce differentiated tissue cells from any individual's stem cell line in industrial quality, quantity and purity. CDI is accelerating the adoption of pluripotent stem cell technology, adapting its methods to fit into standard clinical practice by the creation of individual stem cell lines from a standard blood draw. CDI was founded in 2004 by Dr. James Thomson, a pioneer in human pluripotent stem cell research at the University of Wisconsin-Madison. CDI's facilities are located in Madison, Wisconsin. See http://www.cellulardynamics.com.
MEDIA CONTACTS:Joleen Rau Senior Director, Marketing & Communications Cellular Dynamics International, Inc. 608 310-5142 jrau@cellulardynamics.com
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Presentations at the Society of Toxicology Annual Meeting Demonstrate Superior Predictivity of Cellular Dynamics ...
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albuterol adverse effects - Video
Horizon in new super-cell elite
Cambridge personalised medicines pioneer Horizon Discovery Ltd has landed another showpiece deal as part of a new super-cell consortium.
Business Weekly understands that the UK company stands to make a seven-figure haul over the lifetime of an EU-funded project aimed at understanding hES cell differentiation control.
Horizon provides research tools to support the development of personalised medicines. It has joined the EU-FP7 funded ‘4D-Cell-Fate’ consortium whose aim is to shed light on how stem cell re-programming and differentiation is regulated at the epigenetic level.
As a member of the consortium, Horizon will generate cell-lines harbouring endogenous pathway reporter genes and labelled versions of specific epigenetic target proteins to study their function.
Commercialisation of the output of the programme will be governed by a consortium agreement defined by EU regulation.
4DCellFate brings together 12 groups from nine countries, including academics, research-intensive SMEs, and Pharma, each an international leader in its field, combining expertise in a wide range of cutting-edge technologies and scientific approaches.
The aim of the 4D CellFate project, which is currently funded for five years, is to establish an integrated approach to explore the structure and function of the large multi-protein epigenetic complexes that are involved in control of stem cell self-renewal, lineage commitment, and differentiation.
Horizon will use its proprietary virally-mediated gene-engineering technology, GENESIS™, to alter endogenous genes in hES cells (e.g. via tagging with GFP and HaloTag® technologies) with unprecedented accuracy and precision.
By gaining a greater insight into how Polycomb Repressive Complexes (PRCs), and Nucleosome Remodelling and Deacetylation complexes (NuRD) control stem cell differentiation, it is hoped that better methods will be identified to generate ethical sources of ‘iPS’ stem cells and direct the fate of stem cells into the many forms of specific tissue types that are needed for disease therapy.
Dr Chris Torrance, CSO of Horizon, said: “Generating stem cells and differentiated cell types with greater precision, definition and safety are key areas for delivering on the great promise that stem cell-based therapies could bring to many disease areas.
“Horizon’s gene targeting technology will play a key role in helping to dissect key biological pathways in the fate of stem cells as part of the 4D Cell Fate project. Through this process, new and important approaches to disease therapy will be determined.”
CEO Dr Darrin Disley added: “Our company has a commitment to active involvement in cutting-edge research with leading experts in translational fields, including bringing the power of rAAV-mediated gene targeting technology to the 4D Cell Fate project.”
Original post:
Horizon in new super-cell elite
Radiation Treatment Generates Cancer Stem Cells from Less Aggressive Breast Cancer Cells
Newswise — Breast cancer stem cells are thought to be the sole source of tumor recurrence and are known to be resistant to radiation therapy and don’t respond well to chemotherapy.
Now, researchers with the UCLA Department of Radiation Oncology at UCLA’s Jonsson Comprehensive Cancer Center report for the first time that radiation treatment –despite killing half of all tumor cells during every treatment - transforms other cancer cells into treatment-resistant breast cancer stem cells.
The generation of these breast cancer stem cells counteracts the otherwise highly efficient radiation treatment. If scientists can uncover the mechanisms and prevent this transformation from occurring, radiation treatment for breast cancer could become even more effective, said study senior author Dr. Frank Pajonk, an associate professor of radiation oncology and Jonsson Cancer Center researcher.
“We found that these induced breast cancer stem cells (iBCSC) were generated by radiation-induced activation of the same cellular pathways used to reprogram normal cells into induced pluripotent stem cells (iPS) in regenerative medicine,” said Pajonk, who also is a scientist with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA. “It was remarkable that these breast cancers used the same reprogramming pathways to fight back against the radiation treatment.”
The study appears Feb. 13, 2012 in the early online edition of the peer-reviewed journal Stem Cells.
“Controlling the radiation resistance of breast cancer stem cells and the generation of new iBCSC during radiation treatment may ultimately improve curability and may allow for de-escalation of the total radiation doses currently given to breast cancer patients, thereby reducing acute and long-term adverse effects,” the study states.
There are very few breast cancer stem cells in a larger pool of breast cancer cells. In this study, Pajonk and his team eliminated the smaller pool of breast cancer stem cells and then irradiated the remaining breast cancer cells and placed them into mice.
Using a unique imaging system Pajonk and his team developed to visualize cancer stem cells, the researchers were able to observe their initial generation into iBCSC in response to the radiation treatment. The newly generated iBCSC were remarkably similar to breast cancer stem cells found in tumors that had not been irradiated, Pajonk said.
The team also found that the iBCSC had a more than 30-fold increased ability to form tumors compared to the non-irradiated breast cancer cells from which they originated.
Pajonk said that the study unites the competing models of clonal evolution and the hierarchical organization of breast cancers, as it suggests that undisturbed, growing tumors maintain a small number of cancer stem cells. However, if challenged by various stressors that threaten their numbers, including ionizing radiation, the breast cancer cells generate iBCSC that may, together with the surviving cancer stem cells, repopulate the tumor.
“What is really exciting about this study is that it gives us a much more complex understanding of the interaction of radiation with cancer cells that goes far beyond DNA damage and cell killing,” Pajonk said. “The study may carry enormous potential to make radiation even better.”
Pajonk stressed that breast cancer patients should not be alarmed by the study findings and should continue to undergo radiation if recommended by their oncologists.
“Radiation is an extremely powerful tool in the fight against breast cancer,” he said. “If we can uncover the mechanism driving this transformation, we may be able to stop it and make the therapy even more powerful.”
This study was funded by the National Cancer Institute, the California Breast Cancer Research Program and the Department of Defense.
UCLA's Jonsson Comprehensive Cancer Center has more than 240 researchers and clinicians engaged in disease research, prevention, detection, control, treatment and education. One of the nation's largest comprehensive cancer centers, the Jonsson center is dedicated to promoting research and translating basic science into leading-edge clinical studies. In July 2011, the Jonsson Cancer Center was named among the top 10 cancer centers nationwide by U.S. News & World Report, a ranking it has held for 11 of the last 12 years. For more information on the Jonsson Cancer Center, visit our website at http://www.cancer.ucla.edu.
Comment/Share
Read the original here:
Radiation Treatment Generates Cancer Stem Cells from Less Aggressive Breast Cancer Cells
Life Technologies Scientist Uma Lakshmipathy presents, "Solving Challenges in the Generation of Induced Pluripotent …
Dr. Uma Lakshmipathy speaks at various conferences about work on the creation of integration-free induced pluripotent stem cells at high efficiency with Sendai Virus using the CytoTune™ -iPS Reprogramming Kit. Uma Lakshmipathy's next speaking engagement will be in Mid February at the Stem Cell Banking Conference in London.
Carlsbad, California (PRWEB) February 14, 2012
Uma's last presentation about the Generation of Induced Pluripotent Stem Cells summarized here was also recorded for viewing and placed on the Life Technologies website. (http://find.lifetechnologies.com/stemcells/umavideo/article)
The CytoTune™ - iPS Reprogramming Kit is a high efficiency, integration- free, easy-to-use somatic cell reprogramming kit used in the generation of induced pluripotent stem cells. This kit utilizes Sendai Virus particles of the four Yamanaka factors, which have been shown to be critical in the successful generation of induced pluripotent stem cells.
In her presentations, Uma Lakshmipathy discusses two current challenges faced when generating iPSC including low efficiency and expertise of users.
Low Efficiency
The most common method for generation of induced pluripotent stem cells is the transfection of the four Yamanaka factors using lentivirus or retrovirus. One of the biggest challenges for scientists right now is the low efficiency of iPSC generation. With difficult to transfect cell types or cells from older patients, efficiencies can be 0.001% or lower when using lentiviral or retroviral methods.
Expertise of Users
The second challenge is for users with little expertise that have a difficult time detecting these emerging iPSC colonies. When looking for pluripotent stem cells, people can either pick them up really easily or have trouble deciding what clones to place their bet on.
Efficiency & Safety of IPSC Generation
There are several methods which improve reprogramming efficiency including viral non-integrating and small molecule methods such as mRNA, microRNA and small molecules. The developers of the CytoTune™ -iPS Reprogramming Kit concentrated on a non-integrating viral method utilizing Sendai Virus, a negative sense RNA virus. Sendai Virus is able to infect a wide variety of cell types and generates induced pluripotent stem cells at efficiencies 100-fold higher than lentiviral or retroviral methods.
When comparing efficiency vs. safety of reprogramming methods, small molecules like microRNA, RNA and protein which don’t leave a footprint are safer for cell therapy research; however, the efficiency of generating induced pluripotent stem cells with these methods is pretty low at this point in time.
The highest efficiency so far has been achieved with viral methods such as Retrovirus and Lentivirus. More recently the CytoTune™ -iPS Reprogramming Kit actually exceeds the efficiency that can be obtained with these traditional viral systems and at the same time it is much safer because it is a non-integrating RNA virus. Therefore it will not leave a footprint in the iPSCs that are created.
The CytoTune™ -iPS Reprogramming Kit will:
Reduce hands on time - enables successful iPS reprogramming in one simple transduction Generate more cells - high efficiency reprogramming offers more iPS cells from a single experiment Use in a broad range of experiments - lack of genomic integration and viral remnants allows use from basic to clinical research
Ease of Use
The CytoTune™ -iPS Reprogramming Kit provides a simple system for somatic cell reprogramming. For most cell types, the CytoTune™ -iPS Reprogramming Kit requires only one application of the virus for successful cell reprogramming, unlike other methods such as Lentivirus and mRNA which can require multiple rounds of transduction to produce iPS cells. Selection of colonies is also easier with the CytoTune™ –iPS Reprogramming Kit due to the lower number of non-induced pluripotent stem cells that are generated.
To view this presentation visit http://find.lifetechnologies.com/stemcells/umavideo/article
Uma Lakshmipathy's protocol, "Transfection of Human Embryonic Stem Cells" can be seen here http://bit.ly/y91Gpd
###
Jennifer Hornstein
Life Technologies
(760) 602-4577
Email Information
Radiation treatment transforms breast cancer cells into cancer stem cells
Now, researchers with the UCLA Department of Radiation Oncology at UCLA's Jonsson Comprehensive Cancer Center report for the first time that radiation treatment –despite killing half of all tumor cells during every treatment - transforms other cancer cells into treatment-resistant breast cancer stem cells.
The generation of these breast cancer stem cells counteracts the otherwise highly efficient radiation treatment. If scientists can uncover the mechanisms and prevent this transformation from occurring, radiation treatment for breast cancer could become even more effective, said study senior author Dr. Frank Pajonk, an associate professor of radiation oncology and Jonsson Cancer Center researcher.
"We found that these induced breast cancer stem cells (iBCSC) were generated by radiation-induced activation of the same cellular pathways used to reprogram normal cells into induced pluripotent stem cells (iPS) in regenerative medicine," said Pajonk, who also is a scientist with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA. "It was remarkable that these breast cancers used the same reprogramming pathways to fight back against the radiation treatment."
The study appears Feb. 13, 2012 in the early online edition of the peer-reviewed journal Stem Cells.
"Controlling the radiation resistance of breast cancer stem cells and the generation of new iBCSC during radiation treatment may ultimately improve curability and may allow for de-escalation of the total radiation doses currently given to breast cancer patients, thereby reducing acute and long-term adverse effects," the study states.
There are very few breast cancer stem cells in a larger pool of breast cancer cells. In this study, Pajonk and his team eliminated the smaller pool of breast cancer stem cells and then irradiated the remaining breast cancer cells and placed them into mice.
Using a unique imaging system Pajonk and his team developed to visualize cancer stem cells, the researchers were able to observe their initial generation into iBCSC in response to the radiation treatment. The newly generated iBCSC were remarkably similar to breast cancer stem cells found in tumors that had not been irradiated, Pajonk said.
The team also found that the iBCSC had a more than 30-fold increased ability to form tumors compared to the non-irradiated breast cancer cells from which they originated.
Pajonk said that the study unites the competing models of clonal evolution and the hierarchical organization of breast cancers, as it suggests that undisturbed, growing tumors maintain a small number of cancer stem cells. However, if challenged by various stressors that threaten their numbers, including ionizing radiation, the breast cancer cells generate iBCSC that may, together with the surviving cancer stem cells, repopulate the tumor.
"What is really exciting about this study is that it gives us a much more complex understanding of the interaction of radiation with cancer cells that goes far beyond DNA damage and cell killing," Pajonk said. "The study may carry enormous potential to make radiation even better."
Pajonk stressed that breast cancer patients should not be alarmed by the study findings and should continue to undergo radiation if recommended by their oncologists.
"Radiation is an extremely powerful tool in the fight against breast cancer," he said. "If we can uncover the mechanism driving this transformation, we may be able to stop it and make the therapy even more powerful."
Provided by University of California - Los Angeles
Go here to read the rest:
Radiation treatment transforms breast cancer cells into cancer stem cells
Radiation treatment generates cancer stem cells from less aggressive breast cancer cells, study suggests
ScienceDaily (Feb. 13, 2012) — Breast cancer stem cells are thought to be the sole source of tumor recurrence and are known to be resistant to radiation therapy and don't respond well to chemotherapy.
Now, researchers with the UCLA Department of Radiation Oncology at UCLA's Jonsson Comprehensive Cancer Center report for the first time that radiation treatment -- despite killing half of all tumor cells during every treatment -- transforms other cancer cells into treatment-resistant breast cancer stem cells.
The generation of these breast cancer stem cells counteracts the otherwise highly efficient radiation treatment. If scientists can uncover the mechanisms and prevent this transformation from occurring, radiation treatment for breast cancer could become even more effective, said study senior author Dr. Frank Pajonk, an associate professor of radiation oncology and Jonsson Cancer Center researcher.
"We found that these induced breast cancer stem cells (iBCSC) were generated by radiation-induced activation of the same cellular pathways used to reprogram normal cells into induced pluripotent stem cells (iPS) in regenerative medicine," said Pajonk, who also is a scientist with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA. "It was remarkable that these breast cancers used the same reprogramming pathways to fight back against the radiation treatment."
The study recently appeared in the early online edition of the peer-reviewed journal Stem Cells.
"Controlling the radiation resistance of breast cancer stem cells and the generation of new iBCSC during radiation treatment may ultimately improve curability and may allow for de-escalation of the total radiation doses currently given to breast cancer patients, thereby reducing acute and long-term adverse effects," the study states.
There are very few breast cancer stem cells in a larger pool of breast cancer cells. In this study, Pajonk and his team eliminated the smaller pool of breast cancer stem cells and then irradiated the remaining breast cancer cells and placed them into mice.
Using a unique imaging system Pajonk and his team developed to visualize cancer stem cells, the researchers were able to observe their initial generation into iBCSC in response to the radiation treatment. The newly generated iBCSC were remarkably similar to breast cancer stem cells found in tumors that had not been irradiated, Pajonk said.
The team also found that the iBCSC had a more than 30-fold increased ability to form tumors compared to the non-irradiated breast cancer cells from which they originated.
Pajonk said that the study unites the competing models of clonal evolution and the hierarchical organization of breast cancers, as it suggests that undisturbed, growing tumors maintain a small number of cancer stem cells. However, if challenged by various stressors that threaten their numbers, including ionizing radiation, the breast cancer cells generate iBCSC that may, together with the surviving cancer stem cells, repopulate the tumor.
"What is really exciting about this study is that it gives us a much more complex understanding of the interaction of radiation with cancer cells that goes far beyond DNA damage and cell killing," Pajonk said. "The study may carry enormous potential to make radiation even better."
Pajonk stressed that breast cancer patients should not be alarmed by the study findings and should continue to undergo radiation if recommended by their oncologists.
"Radiation is an extremely powerful tool in the fight against breast cancer," he said. "If we can uncover the mechanism driving this transformation, we may be able to stop it and make the therapy even more powerful."
This study was funded by the National Cancer Institute, the California Breast Cancer Research Program and the Department of Defense.
Recommend this story on Facebook, Twitter,
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Story Source:
The above story is reprinted from materials provided by University of California, Los Angeles (UCLA), Health Sciences, via Newswise.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
Chann Lagadec, Erina Vlashi, Lorenza Della Donna, Carmen Dekmezian and Frank Pajonk. Radiation-induced Reprograming of Breast Cancer Cells. Stem Cells, 10 FEB 2012 DOI: 10.1002/stem.1058
Note: If no author is given, the source is cited instead.
Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of ScienceDaily or its staff.
Radiation therapy transforms breast cancer cells into cancer stem cells
Washington, Feb 14 (ANI): Researchers have shown for the first time that radiation treatment -despite killing half of all tumour cells during every cycle - transforms other cancer cells into treatment-resistant breast cancer stem cells.
According to researchers with the UCLA Department of Radiation Oncology at UCLA's Jonsson Comprehensive Cancer Center, the generation of these breast cancer stem cells counteracts the otherwise highly efficient radiation treatment.
If scientists can uncover the mechanisms and prevent this transformation from occurring, radiation treatment for breast cancer could become even more effective, said study senior author Dr. Frank Pajonk, an associate professor of radiation oncology and Jonsson Cancer Center researcher.
"We found that these induced breast cancer stem cells (iBCSC) were generated by radiation-induced activation of the same cellular pathways used to reprogram normal cells into induced pluripotent stem cells (iPS) in regenerative medicine," said Pajonk, who also is a scientist with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA.
"It was remarkable that these breast cancers used the same reprogramming pathways to fight back against the radiation treatment."
"Controlling the radiation resistance of breast cancer stem cells and the generation of new iBCSC during radiation treatment may ultimately improve curability and may allow for de-escalation of the total radiation doses currently given to breast cancer patients, thereby reducing acute and long-term adverse effects," the study stated.
There are very few breast cancer stem cells in a larger pool of breast cancer cells. In this study, Pajonk and his team eliminated the smaller pool of breast cancer stem cells and then irradiated the remaining breast cancer cells and placed them into mice.
Using a unique imaging system Pajonk and his team developed to visualize cancer stem cells, the researchers were able to observe their initial generation into iBCSC in response to the radiation treatment.
The newly generated iBCSC were remarkably similar to breast cancer stem cells found in tumors that had not been irradiated, Pajonk said.
The team also found that the iBCSC had a more than 30-fold increased ability to form tumors compared to the non-irradiated breast cancer cells from which they originated.
Pajonk said that the study unites the competing models of clonal evolution and the hierarchical organization of breast cancers, as it suggests that undisturbed, growing tumors maintain a small number of cancer stem cells.
However, if challenged by various stressors that threaten their numbers, including ionizing radiation, the breast cancer cells generate iBCSC that may, together with the surviving cancer stem cells, repopulate the tumour.
"What is really exciting about this study is that it gives us a much more complex understanding of the interaction of radiation with cancer cells that goes far beyond DNA damage and cell killing," Pajonk said.
"The study may carry enormous potential to make radiation even better."
Pajonk stressed that breast cancer patients should not be alarmed by the study findings and should continue to undergo radiation if recommended by their oncologists.
"Radiation is an extremely powerful tool in the fight against breast cancer," he said.
"If we can uncover the mechanism driving this transformation, we may be able to stop it and make the therapy even more powerful," Pajonk added.
The study has been published in the online edition of peer-reviewed journal Stem Cells. (ANI)
Go here to see the original:
Radiation therapy transforms breast cancer cells into cancer stem cells
Life Technologies Scientist Uma Lakshmipathy presents, "Solving Challenges in the Generation of Induced Pluripotent …
Dr. Uma Lakshmipathy speaks at various conferences about work on the creation of integration-free induced pluripotent stem cells at high efficiency with Sendai Virus using the CytoTune™ -iPS Reprogramming Kit. Uma Lakshmipathy's next speaking engagement will be in Mid February at the Stem Cell Banking Conference in London.
Carlsbad, California (PRWEB) February 14, 2012
Uma's last presentation about the Generation of Induced Pluripotent Stem Cells summarized here was also recorded for viewing and placed on the Life Technologies website. (http://find.lifetechnologies.com/stemcells/umavideo/article)
The CytoTune™ - iPS Reprogramming Kit is a high efficiency, integration- free, easy-to-use somatic cell reprogramming kit used in the generation of induced pluripotent stem cells. This kit utilizes Sendai Virus particles of the four Yamanaka factors, which have been shown to be critical in the successful generation of induced pluripotent stem cells.
In her presentations, Uma Lakshmipathy discusses two current challenges faced when generating iPSC including low efficiency and expertise of users.
Low Efficiency
The most common method for generation of induced pluripotent stem cells is the transfection of the four Yamanaka factors using lentivirus or retrovirus. One of the biggest challenges for scientists right now is the low efficiency of iPSC generation. With difficult to transfect cell types or cells from older patients, efficiencies can be 0.001% or lower when using lentiviral or retroviral methods.
Expertise of Users
The second challenge is for users with little expertise that have a difficult time detecting these emerging iPSC colonies. When looking for pluripotent stem cells, people can either pick them up really easily or have trouble deciding what clones to place their bet on.
Efficiency & Safety of IPSC Generation
There are several methods which improve reprogramming efficiency including viral non-integrating and small molecule methods such as mRNA, microRNA and small molecules. The developers of the CytoTune™ -iPS Reprogramming Kit concentrated on a non-integrating viral method utilizing Sendai Virus, a negative sense RNA virus. Sendai Virus is able to infect a wide variety of cell types and generates induced pluripotent stem cells at efficiencies 100-fold higher than lentiviral or retroviral methods.
When comparing efficiency vs. safety of reprogramming methods, small molecules like microRNA, RNA and protein which don’t leave a footprint are safer for cell therapy research; however, the efficiency of generating induced pluripotent stem cells with these methods is pretty low at this point in time.
The highest efficiency so far has been achieved with viral methods such as Retrovirus and Lentivirus. More recently the CytoTune™ -iPS Reprogramming Kit actually exceeds the efficiency that can be obtained with these traditional viral systems and at the same time it is much safer because it is a non-integrating RNA virus. Therefore it will not leave a footprint in the iPSCs that are created.
The CytoTune™ -iPS Reprogramming Kit will:
Reduce hands on time - enables successful iPS reprogramming in one simple transduction Generate more cells - high efficiency reprogramming offers more iPS cells from a single experiment Use in a broad range of experiments - lack of genomic integration and viral remnants allows use from basic to clinical research
Ease of Use
The CytoTune™ -iPS Reprogramming Kit provides a simple system for somatic cell reprogramming. For most cell types, the CytoTune™ -iPS Reprogramming Kit requires only one application of the virus for successful cell reprogramming, unlike other methods such as Lentivirus and mRNA which can require multiple rounds of transduction to produce iPS cells. Selection of colonies is also easier with the CytoTune™ –iPS Reprogramming Kit due to the lower number of non-induced pluripotent stem cells that are generated.
To view this presentation visit http://find.lifetechnologies.com/stemcells/umavideo/article
Uma Lakshmipathy's protocol, "Transfection of Human Embryonic Stem Cells" can be seen here http://bit.ly/y91Gpd
###
Jennifer Hornstein
Life Technologies
(760) 602-4577
Email Information
Radiation Treatment Generates Cancer Stem Cells from Less Aggressive Breast Cancer Cells
Newswise — Breast cancer stem cells are thought to be the sole source of tumor recurrence and are known to be resistant to radiation therapy and don’t respond well to chemotherapy.
Now, researchers with the UCLA Department of Radiation Oncology at UCLA’s Jonsson Comprehensive Cancer Center report for the first time that radiation treatment –despite killing half of all tumor cells during every treatment - transforms other cancer cells into treatment-resistant breast cancer stem cells.
The generation of these breast cancer stem cells counteracts the otherwise highly efficient radiation treatment. If scientists can uncover the mechanisms and prevent this transformation from occurring, radiation treatment for breast cancer could become even more effective, said study senior author Dr. Frank Pajonk, an associate professor of radiation oncology and Jonsson Cancer Center researcher.
“We found that these induced breast cancer stem cells (iBCSC) were generated by radiation-induced activation of the same cellular pathways used to reprogram normal cells into induced pluripotent stem cells (iPS) in regenerative medicine,” said Pajonk, who also is a scientist with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA. “It was remarkable that these breast cancers used the same reprogramming pathways to fight back against the radiation treatment.”
The study appears DATE in the early online edition of the peer-reviewed journal Stem Cells.
“Controlling the radiation resistance of breast cancer stem cells and the generation of new iBCSC during radiation treatment may ultimately improve curability and may allow for de-escalation of the total radiation doses currently given to breast cancer patients, thereby reducing acute and long-term adverse effects,” the study states.
There are very few breast cancer stem cells in a larger pool of breast cancer cells. In this study, Pajonk and his team eliminated the smaller pool of breast cancer stem cells and then irradiated the remaining breast cancer cells and placed them into mice.
Using a unique imaging system Pajonk and his team developed to visualize cancer stem cells, the researchers were able to observe their initial generation into iBCSC in response to the radiation treatment. The newly generated iBCSC were remarkably similar to breast cancer stem cells found in tumors that had not been irradiated, Pajonk said.
The team also found that the iBCSC had a more than 30-fold increased ability to form tumors compared to the non-irradiated breast cancer cells from which they originated.
Pajonk said that the study unites the competing models of clonal evolution and the hierarchical organization of breast cancers, as it suggests that undisturbed, growing tumors maintain a small number of cancer stem cells. However, if challenged by various stressors that threaten their numbers, including ionizing radiation, the breast cancer cells generate iBCSC that may, together with the surviving cancer stem cells, repopulate the tumor.
“What is really exciting about this study is that it gives us a much more complex understanding of the interaction of radiation with cancer cells that goes far beyond DNA damage and cell killing,” Pajonk said. “The study may carry enormous potential to make radiation even better.”
Pajonk stressed that breast cancer patients should not be alarmed by the study findings and should continue to undergo radiation if recommended by their oncologists.
“Radiation is an extremely powerful tool in the fight against breast cancer,” he said. “If we can uncover the mechanism driving this transformation, we may be able to stop it and make the therapy even more powerful.”
This study was funded by the National Cancer Institute, the California Breast Cancer Research Program and the Department of Defense.
UCLA's Jonsson Comprehensive Cancer Center has more than 240 researchers and clinicians engaged in disease research, prevention, detection, control, treatment and education. One of the nation's largest comprehensive cancer centers, the Jonsson center is dedicated to promoting research and translating basic science into leading-edge clinical studies. In July 2011, the Jonsson Cancer Center was named among the top 10 cancer centers nationwide by U.S. News & World Report, a ranking it has held for 11 of the last 12 years. For more information on the Jonsson Cancer Center, visit our website at http://www.cancer.ucla.edu.
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Visit link:
Radiation Treatment Generates Cancer Stem Cells from Less Aggressive Breast Cancer Cells
Radiation treatment generates cancer stem cells from less aggressive breast cancer cells, study suggests
ScienceDaily (Feb. 13, 2012) — Breast cancer stem cells are thought to be the sole source of tumor recurrence and are known to be resistant to radiation therapy and don't respond well to chemotherapy.
Now, researchers with the UCLA Department of Radiation Oncology at UCLA's Jonsson Comprehensive Cancer Center report for the first time that radiation treatment -- despite killing half of all tumor cells during every treatment -- transforms other cancer cells into treatment-resistant breast cancer stem cells.
The generation of these breast cancer stem cells counteracts the otherwise highly efficient radiation treatment. If scientists can uncover the mechanisms and prevent this transformation from occurring, radiation treatment for breast cancer could become even more effective, said study senior author Dr. Frank Pajonk, an associate professor of radiation oncology and Jonsson Cancer Center researcher.
"We found that these induced breast cancer stem cells (iBCSC) were generated by radiation-induced activation of the same cellular pathways used to reprogram normal cells into induced pluripotent stem cells (iPS) in regenerative medicine," said Pajonk, who also is a scientist with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA. "It was remarkable that these breast cancers used the same reprogramming pathways to fight back against the radiation treatment."
The study recently appeared in the early online edition of the peer-reviewed journal Stem Cells.
"Controlling the radiation resistance of breast cancer stem cells and the generation of new iBCSC during radiation treatment may ultimately improve curability and may allow for de-escalation of the total radiation doses currently given to breast cancer patients, thereby reducing acute and long-term adverse effects," the study states.
There are very few breast cancer stem cells in a larger pool of breast cancer cells. In this study, Pajonk and his team eliminated the smaller pool of breast cancer stem cells and then irradiated the remaining breast cancer cells and placed them into mice.
Using a unique imaging system Pajonk and his team developed to visualize cancer stem cells, the researchers were able to observe their initial generation into iBCSC in response to the radiation treatment. The newly generated iBCSC were remarkably similar to breast cancer stem cells found in tumors that had not been irradiated, Pajonk said.
The team also found that the iBCSC had a more than 30-fold increased ability to form tumors compared to the non-irradiated breast cancer cells from which they originated.
Pajonk said that the study unites the competing models of clonal evolution and the hierarchical organization of breast cancers, as it suggests that undisturbed, growing tumors maintain a small number of cancer stem cells. However, if challenged by various stressors that threaten their numbers, including ionizing radiation, the breast cancer cells generate iBCSC that may, together with the surviving cancer stem cells, repopulate the tumor.
"What is really exciting about this study is that it gives us a much more complex understanding of the interaction of radiation with cancer cells that goes far beyond DNA damage and cell killing," Pajonk said. "The study may carry enormous potential to make radiation even better."
Pajonk stressed that breast cancer patients should not be alarmed by the study findings and should continue to undergo radiation if recommended by their oncologists.
"Radiation is an extremely powerful tool in the fight against breast cancer," he said. "If we can uncover the mechanism driving this transformation, we may be able to stop it and make the therapy even more powerful."
This study was funded by the National Cancer Institute, the California Breast Cancer Research Program and the Department of Defense.
Recommend this story on Facebook, Twitter,
and Google +1:
Other bookmarking and sharing tools:
Story Source:
The above story is reprinted from materials provided by University of California, Los Angeles (UCLA), Health Sciences, via Newswise.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
Chann Lagadec, Erina Vlashi, Lorenza Della Donna, Carmen Dekmezian and Frank Pajonk. Radiation-induced Reprograming of Breast Cancer Cells. Stem Cells, 10 FEB 2012 DOI: 10.1002/stem.1058
Note: If no author is given, the source is cited instead.
Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of ScienceDaily or its staff.
See the article here:
Radiation treatment generates cancer stem cells from less aggressive breast cancer cells, study suggests
Radiation treatment transforms breast cancer cells into cancer stem cells
Now, researchers with the UCLA Department of Radiation Oncology at UCLA's Jonsson Comprehensive Cancer Center report for the first time that radiation treatment –despite killing half of all tumor cells during every treatment - transforms other cancer cells into treatment-resistant breast cancer stem cells.
The generation of these breast cancer stem cells counteracts the otherwise highly efficient radiation treatment. If scientists can uncover the mechanisms and prevent this transformation from occurring, radiation treatment for breast cancer could become even more effective, said study senior author Dr. Frank Pajonk, an associate professor of radiation oncology and Jonsson Cancer Center researcher.
"We found that these induced breast cancer stem cells (iBCSC) were generated by radiation-induced activation of the same cellular pathways used to reprogram normal cells into induced pluripotent stem cells (iPS) in regenerative medicine," said Pajonk, who also is a scientist with the Eli and Edythe Broad Center of Regenerative Medicine at UCLA. "It was remarkable that these breast cancers used the same reprogramming pathways to fight back against the radiation treatment."
The study appears DATE in the early online edition of the peer-reviewed journal Stem Cells.
"Controlling the radiation resistance of breast cancer stem cells and the generation of new iBCSC during radiation treatment may ultimately improve curability and may allow for de-escalation of the total radiation doses currently given to breast cancer patients, thereby reducing acute and long-term adverse effects," the study states.
There are very few breast cancer stem cells in a larger pool of breast cancer cells. In this study, Pajonk and his team eliminated the smaller pool of breast cancer stem cells and then irradiated the remaining breast cancer cells and placed them into mice.
Using a unique imaging system Pajonk and his team developed to visualize cancer stem cells, the researchers were able to observe their initial generation into iBCSC in response to the radiation treatment. The newly generated iBCSC were remarkably similar to breast cancer stem cells found in tumors that had not been irradiated, Pajonk said.
The team also found that the iBCSC had a more than 30-fold increased ability to form tumors compared to the non-irradiated breast cancer cells from which they originated.
Pajonk said that the study unites the competing models of clonal evolution and the hierarchical organization of breast cancers, as it suggests that undisturbed, growing tumors maintain a small number of cancer stem cells. However, if challenged by various stressors that threaten their numbers, including ionizing radiation, the breast cancer cells generate iBCSC that may, together with the surviving cancer stem cells, repopulate the tumor.
"What is really exciting about this study is that it gives us a much more complex understanding of the interaction of radiation with cancer cells that goes far beyond DNA damage and cell killing," Pajonk said. "The study may carry enormous potential to make radiation even better."
Pajonk stressed that breast cancer patients should not be alarmed by the study findings and should continue to undergo radiation if recommended by their oncologists.
"Radiation is an extremely powerful tool in the fight against breast cancer," he said. "If we can uncover the mechanism driving this transformation, we may be able to stop it and make the therapy even more powerful."
Provided by University of California - Los Angeles
Read more from the original source:
Radiation treatment transforms breast cancer cells into cancer stem cells
EC transfers Basti Commissioner to pacify agitating IPS officers
Home > News > more-news
Lucknow, Jan 29 : In order to pacify the agitating Indian Police Services(IPS) officers in Uttar Pradesh, Election Commission(EC) tonight transferred the controversial Basti Divisional Commissioner Anurag Srivastava.
Mr Sanjiv Kumar, Principal Secretary in the Rrural Development department has been appointed as the new commissioner of Basti while Srivastava have been kept in waiting, official sources here tonight said.
However, the IPS Association announced that they will continue to agitate against the insult of the Sidhardhnagar SP Mohit Gupta till the Commissioner was punished besides he seeds unconditional apology from the SP. The Association has called a meeting of the officers on Tuesday evening to decide on the course of future action.
A revolt like situation arose when over 16 IPS offered to resign following insult of Superintendent of Police(SP) of Sidharthnagar by senior IAS officer and Commissioner of Basti even though Uttar Pradesh government today set up a two member committee to probe into the matter while a clarification has been sought from the IAS officer.
Over 16 IPS officers including 7 of the 2006 batch tendered their resignation after the Sidharthanagar SP Mohit Gupta was transferred last night.
UP government however acted swiftly and after a delegation of the IPS Association met state Cabinet Secetary Shashank Shekhar Singh, a two member committee comprising Industrial development Commissioner (IDC) V N Garg and Deputy Inspector general of Police( Anti corruption cell) Arun Kumar Gupta was formed to probe into the matter and give their recommendation within three days time.
Meanwhile, Basti Commissioner Anurag Srivastava, against whom the IPS have lodged the protest, have been asked by the state government to clarify about his stand by January 31. (UNI)
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EC transfers Basti Commissioner to pacify agitating IPS officers
New era of medicine in the offing, says scientist
The Hindu Prof. Shinya Yamanaka of Centre for iPS Cell Research and Application, Japan, delivering a lecture in New Delhi on Friday. Photo: R.V.Moorthy
Renowned Japanese scientist Shinya Yamanaka, who achieved a major breakthrough in the emerging area of stem cell research by creating a possible alternative to embryonic stem cells in 2007, expressed confidence here on Friday that drugs would be available soon for diseases for which therapies are yet to be found.
Delivering a lecture on “New Era of Medicine with iPS Cells” organised jointly by Cell Press and TNQ Books and Journals, Prof. Yamanaka said the cells -- “induced pluripotent stem cells [iPS Cells]'' -- developed by him and his team would not only help overcome the ethical issues surrounding use of embryonic stem cells for treatment of diseases like spinal cord injuries, Type I diabetes or macular diseases but also help in development of drugs for conditions like motor neuron disease.
Embryonic stem cell therapy is considered important as it offers immense possibilities for treatment of a wide range of diseases and conditions since the cells proliferaterapidly and are pluripotent or possess the capability to differentiate into any type of cell, said Prof. Yamanaka. But it suffers from a major ethical issue as it involves use of live human embryos, Prof. Yamanaka pointed out. He said if there was a post-transplant rejection, they cannot be used from the patient's own cell.The iPS cells, on the other hand, are created from adult skin cells and do not have these two problems, while at the same time they provide for rapid proliferation and the possibility to differentiate into any type of cell, he said. Prof. Yamanaka and his team generated iPS mouse cells in 2006 and followed up with iPS cells developed from human skin cells in 2007.
Speaking about the potentials of iPS cells, he said studies using the cells for treatment of spinal cord injuries have already shown good results in mouse and monkey specimens and in two to three years scientists would be ready to go in for clinical trials. He, however, admitted that there are several challenges before the new technology. Its safety is yet to be proved completely and the process of deriving patient-specific iPS cells is time-consuming and expensive.
He expressed hope that scientists who are working on itwould overcome the challenges and a new era in medical treatment would emerge soon.
Union Human Resource Development Minister Kapil Sibal, who introduced him, said his Ministry along with the Ministries of Health and Science & Technology would take steps for Indian scientists to collaborate with him.
TNQ Books and Journals Managing Director Mariam Ram and Cell Press Executive Editor Emilie Marcus also spoke.
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New era of medicine in the offing, says scientist