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Diabetes drug kills cancer stem cells in combination treatment in mice
September 14, 2009PHILADELPHIA - In a one-two punch, a familiar diabetes drug reduced tumors faster and prolonged remission in mice longer than chemotherapy alone by targeting cancer stem cells, Harvard Medical School researchers reported in the September 14 online first edition of Cancer Research, a journal of the American Association for Cancer Research.
"We have found a compound selective for cancer stem cells," said lead researcher Kevin Struhl, Ph.D., the David Wesley Gaiser professor of biological chemistry and molecular pharmacology at Harvard Medical School. "What's different is that ours is a first-line diabetes drug."
These findings add to a growing body of preliminary evidence in cells, mice and people that metformin may improve breast cancer outcomes in people. In this study, the diabetes drug seemed to work independently of its ability to improve insulin sensitivity and lower blood sugar and insulin levels, all of which are also associated with better breast cancer outcomes.
The results fit within the cancer stem cell hypothesis, an intensely studied idea that small subsets of cancer cells have a special power to initiate tumors, fuel tumor growth and promote recurrence of cancer. Cancer stem cells appear to resist conventional chemotherapies, which kill the bulk of the tumor.
"There is a big desire to find drugs specific to cancer stem cells," said Struhl. "The cancer stem cell hypothesis says you cannot cure cancer unless you also get rid of the cancer stem cells. From a purely practical point of view, this could be tested in humans. It's already [in use as] a first-line diabetes drug."
The possible usefulness of a diabetes drug against cancer lends credence to an emerging idea that, in the vast and complex alphabet soup of molecular interactions within cells, a relatively few biological pathways will turn out to be most important for many different diseases, Struhl suggested.
In experiments led by postdoctoral fellows Heather Hirsch, Ph.D., and Dimitrios Iliopoulos, Ph.D., the combination of metformin and the cancer drug doxorubicin killed human cancer stem cells and non-stem cancer cells in culture. The researchers used four genetically distinct breast cancer cell lines.
In mice, pretreatment with metformin prevented the otherwise dramatic ability of human breast cancer stem cells to form tumors. In other mice where tumors took hold for 10 days, the combination therapy also reduced tumor mass more quickly and prevented relapse for longer than doxorubicin alone. In the two months between the end of treatment and the end of the experiment, tumors regrew in the mice treated with chemotherapy alone, but not in those who received both drugs. Metformin was ineffective in treating tumors when used alone.
"This is an exciting study," said Jennifer Ligibel, M.D., a medical oncologist at the Dana-Farber Cancer Institute and a Harvard Medical School instructor in medicine. Ligibel and colleagues at the National Cancer Institute of Canada Clinical Trials Group are developing a large-scale phase II trial and will study its metformin's impact on recurrence in women treated for early stage breast cancer.
"There is a lot of interest in studying metformin in breast cancer, but so far we do not have direct evidence that metformin will improve outcomes in patients," said Ligibel, who was not involved in the current study "That's what this trial is for."
So far, observational studies have suggested a lower risk of cancers, including breast cancer, and better response to chemotherapy in patients with diabetes who are treated with metformin, she said. Results of basic science studies have also suggested plausible biological mechanisms. The study from the Struhl lab suggests a potential new pathway through which metformin could have an effect on breast cancer cells, according to Ligibel.
In their search for compounds that selectively destroy cancer stem cells, researchers hope to improve cancer outcomes. But the story is never as simple in human cancers, according to Kornelia Polyak, M.D., Ph.D., a breast cancer researcher at the Dana-Farber Cancer Institute and an associate professor of medicine at Harvard Medical School.
Cancer stem cells are a shifty target, said Polyak, who was not involved in the current study. For example, any cancer cell can acquire the properties of a cancer stem cell, and cancer stem cells can change into non-stem cancer cells, which can be just as deadly. Clinical trials in people are needed to test these ideas, according to Polyak.
The study by Struhl and colleagues is an offshoot of a larger project in his lab to systematically track how gene activity changes when cells transform into cancer. These changes were remarkably similar to gene dynamics in diabetes and other inflammatory conditions.
The researchers reasoned that if a common genetic pathway underlies different diseases, drugs that work against one disease might work against another. In a screen, the most effective drug inhibiting the transformation of cells into cancer was metformin, which led to the experiments in this study. They were further encouraged by the low dose of metformin needed for the effect in the laboratory, compared to the amount needed for analogous molecular experiments in basic diabetes research. The relative dosage for treating or preventing cancer is unknown and untested in people.
Struhl and Harvard Medical School have applied for a patent for a combined therapy of metformin and a lower dose of chemotherapy, which is being tested in animals. The National Institutes of Health and the American Cancer Society funded this research.
News Briefing: The American Association for Cancer Research will host a news briefing about the results of this study, which is published online first in Cancer Research.
Date: Monday, Sept. 14, 2009
Time: 10:00 a.m. ET
Reporters can dial-in using the following information:
Dial-In (U.S. and Canada): (800) 340-6945
Dial-In (International): (706) 679-5207
Code: 28156127
Topic: AACR
Panelists:
Moderator - Frank Rauscher, III, Ph.D.
Editor in Chief, Cancer Research
Professor, Gene Expression and Regulation Program
The Wistar Institute
Kevin Struhl, Ph.D.
David Wesley Gaiser Professor of Biological Chemistry and Molecular Pharmacology
Harvard Medical School
George Prendergast, Ph.D.
President, CEO and Professor
Lankenau Institute for Medical Research
Jennifer Ligibel, M.D.
Medical Oncologist
Dana-Farber Cancer Institute
American Association for Cancer Research
The results fit within the cancer stem cell hypothesis, an intensely studied idea that small subsets of cancer cells have a special power to initiate tumors, fuel tumor growth and promote recurrence of cancer. Cancer stem cells appear to resist conventional chemotherapies, which kill the bulk of the tumor.
"There is a big desire to find drugs specific to cancer stem cells," said Struhl. "The cancer stem cell hypothesis says you cannot cure cancer unless you also get rid of the cancer stem cells. From a purely practical point of view, this could be tested in humans. It's already [in use as] a first-line diabetes drug."
The possible usefulness of a diabetes drug against cancer lends credence to an emerging idea that, in the vast and complex alphabet soup of molecular interactions within cells, a relatively few biological pathways will turn out to be most important for many different diseases, Struhl suggested.
In experiments led by postdoctoral fellows Heather Hirsch, Ph.D., and Dimitrios Iliopoulos, Ph.D., the combination of metformin and the cancer drug doxorubicin killed human cancer stem cells and non-stem cancer cells in culture. The researchers used four genetically distinct breast cancer cell lines.
In mice, pretreatment with metformin prevented the otherwise dramatic ability of human breast cancer stem cells to form tumors. In other mice where tumors took hold for 10 days, the combination therapy also reduced tumor mass more quickly and prevented relapse for longer than doxorubicin alone. In the two months between the end of treatment and the end of the experiment, tumors regrew in the mice treated with chemotherapy alone, but not in those who received both drugs. Metformin was ineffective in treating tumors when used alone.
"This is an exciting study," said Jennifer Ligibel, M.D., a medical oncologist at the Dana-Farber Cancer Institute and a Harvard Medical School instructor in medicine. Ligibel and colleagues at the National Cancer Institute of Canada Clinical Trials Group are developing a large-scale phase II trial and will study its metformin's impact on recurrence in women treated for early stage breast cancer.
"There is a lot of interest in studying metformin in breast cancer, but so far we do not have direct evidence that metformin will improve outcomes in patients," said Ligibel, who was not involved in the current study "That's what this trial is for."
So far, observational studies have suggested a lower risk of cancers, including breast cancer, and better response to chemotherapy in patients with diabetes who are treated with metformin, she said. Results of basic science studies have also suggested plausible biological mechanisms. The study from the Struhl lab suggests a potential new pathway through which metformin could have an effect on breast cancer cells, according to Ligibel.
In their search for compounds that selectively destroy cancer stem cells, researchers hope to improve cancer outcomes. But the story is never as simple in human cancers, according to Kornelia Polyak, M.D., Ph.D., a breast cancer researcher at the Dana-Farber Cancer Institute and an associate professor of medicine at Harvard Medical School.
Cancer stem cells are a shifty target, said Polyak, who was not involved in the current study. For example, any cancer cell can acquire the properties of a cancer stem cell, and cancer stem cells can change into non-stem cancer cells, which can be just as deadly. Clinical trials in people are needed to test these ideas, according to Polyak.
The study by Struhl and colleagues is an offshoot of a larger project in his lab to systematically track how gene activity changes when cells transform into cancer. These changes were remarkably similar to gene dynamics in diabetes and other inflammatory conditions.
The researchers reasoned that if a common genetic pathway underlies different diseases, drugs that work against one disease might work against another. In a screen, the most effective drug inhibiting the transformation of cells into cancer was metformin, which led to the experiments in this study. They were further encouraged by the low dose of metformin needed for the effect in the laboratory, compared to the amount needed for analogous molecular experiments in basic diabetes research. The relative dosage for treating or preventing cancer is unknown and untested in people.
Struhl and Harvard Medical School have applied for a patent for a combined therapy of metformin and a lower dose of chemotherapy, which is being tested in animals. The National Institutes of Health and the American Cancer Society funded this research.
News Briefing: The American Association for Cancer Research will host a news briefing about the results of this study, which is published online first in Cancer Research.
Date: Monday, Sept. 14, 2009
Time: 10:00 a.m. ET
Reporters can dial-in using the following information:
Dial-In (U.S. and Canada): (800) 340-6945
Dial-In (International): (706) 679-5207
Code: 28156127
Topic: AACR
Panelists:
Moderator - Frank Rauscher, III, Ph.D.
Editor in Chief, Cancer Research
Professor, Gene Expression and Regulation Program
The Wistar Institute
Kevin Struhl, Ph.D.
David Wesley Gaiser Professor of Biological Chemistry and Molecular Pharmacology
Harvard Medical School
George Prendergast, Ph.D.
President, CEO and Professor
Lankenau Institute for Medical Research
Jennifer Ligibel, M.D.
Medical Oncologist
Dana-Farber Cancer Institute
American Association for Cancer Research
Cancer Stem Cells Current Events and Cancer Stem Cells News RSSGovernor recognizes stem cell research at Einstein
Albert Einstein College of Medicine of Yeshiva University hosted a roundtable discussion on stem cell research with New York Governor David A. Paterson today.
MDC scientists show how hematopoietic stem cell development is regulated
During cell division, whether hematopoietic stem cells (HSCs) will develop into new stem cells (self-renewal) or differentiate into other blood cells depends on a chemical process called DNA methylation.
Echoes of phlogiston in stem cell biology
Before it was learned that matter burns by taking up oxygen, most chemists sought to explain combustion as the release of a mysterious substance, which they named "phlogiston".
Penn State College of Medicine research isolates liver cancer stem cells prior to tumor formation
Penn State College of Medicine researchers, in collaboration with colleagues at the University of Southern California, have taken an important step in understanding the role of stem cells in development of liver cancer.
Turning back the clock: Fasting prolongs reproductive life span
Scientific dogma has long asserted that females are born with their entire lifetime's supply of eggs, and once they're gone, they're gone.
First compound that specifically kills cancer stem cells found
The cancer stem cells that drive tumor growth and resist chemotherapies and radiation treatments that kill other cancer cells aren't invincible after all.
STAT3 Gene Regulates Cancer Stem Cells in Brain Cancer
In a study published online in advance of print in Stem Cells, Tufts researchers report that the STAT3 gene regulates cancer stem cells in brain cancer. Cancer stem cells have many characteristics of stem cells and are thought to be the cells that drive tumor formation.
Stripping leukemia-initiating cells of their 'invisibility cloak'
Two new studies reveal a way to increase the body's appetite for gobbling up the cancer stem cells responsible for acute myeloid leukemia (AML), a form of cancer with a particularly poor survival rate.
Toronto researcher's discovery points to a new treatment avenue for acute myeloid leukemia
Dr. John Dick, Senior Scientist at the Ontario Cancer Institute, the research arm of Princess Margaret Hospital, co-led a multinational team that has developed the first leukemia therapy that targets a protein, CD123, on the surface of cancer stem cells that drive acute myeloid leukemia (AML), which is an aggressive disease with a poor outcome.
Neural stem cell differentiation factor discovered
Neural stem cells represent the cellular backup of our brain. These cells are capable of self-renewal to form new stem cells or differentiate into neurons, astrocytes or oligodendrocytes.
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