Researchers found ideal time to collect embryonic stem cells to treat Parkinson’s disease

At the 38th annual meeting of the Society for Neuroscience, researchers have identified an ideal time to collect human embryonic stem cells to treat Parkinson’s disease.

Lorraine Iacovitti, Ph.D., professor and interim director of the Farber Institute for Neurosciences of Thomas Jefferson University have found that a stage during dopamine neuron differentiation can be the ideal time for that. The researcher team found that neural progenitor cells that express the gene Lmx1a are committed to the midbrain dopamine neuron lineage, but still retain proliferative capacity. Because of these characteristics, the stage at which Lmx1a is expressed may be ideal for transplantation.

The Lmx1a-positive cells cannot be identified solely by this transcription factor. However, Dr. Iacovitti and her team also found that a large percentage of the Lmx1a-positive cells express a cell surface protein called TrkB. This protein was not expressed on any of the other cell types identified in the cell culture. With TrkB as a cell surface marker, dopamine neuron progenitor cells derived from human embryonic stem cells can be selected from a heterogenous population using magnetic-activated cell sorting (MACS) or fluorescence-activated cell sorting (FACS).

Source: Science Daily

Adult Stem Cell Research Reverses Effects of Parkinson's Disease in Human Trial

by Steven Ertelt
LifeNews.com Editor
February 16, 2009

Los Angeles, CA (LifeNews.com) -- Scientists have published a paper in a medical journal describing the results of the world's first clinical trial using autologous neural stem cells for the treatment of Parkinson's disease. A leading bioethics watchdog says the results show more money should be put behind adult stem cells.

UCLA researchers published their results in February issue of the Bentham Open Stem Cell Journal which outlines the long term results of the trial.

"We have documented the first successful adult neural stem cell transplantation to reverse the effects of Parkinson's disease and demonstrated the long term safety and therapeutic effects of this approach," says lead author Dr. Michel Levesque.

The paper describes how Levesque's team was able to isolate patient-derived neural stem cells, multiply them in vitro and ultimately differentiate them to produce mature neurons before they are reintroduced into the brain.

The team was able to inject the adult stem cells without the need for immunosuppressants. Unlike embryonic stem cells, adult stem cell injections don't cause a patient's immune system to reject the cells.

The adult stem cells were highly beneficial for the patient involved in the study.

"Of particular note are the striking results this study yielded -- for the five years following the procedure the patient's motor scales improved by over 80% for at least 36 months," Levesque wrote.

He said he hoped a larger clinical trial would replicate the findings.

Dr. David Prentice, a former biology professor at Indiana State University who is now a fellow with the Family Research Council, tells LifeNews.com that the results of the study are wonderful news for patients.

"This evidence had been presented previously, but we now have the peer-reviewed scientific evidence for the effectiveness of adult stem cells in alleviating Parkinson's symptoms," he said. "While the data show that the technique needs refinement, this patient went for several years with little to no symptoms of his disease, even with only half of the brain treated with his own adult stem cells."

Prentice says the results continue to prove that adult stem cells outpace their embryonic counterparts.

"People need to take notice that it is not embryonic stem cells that provide promise of treatments in the future, but rather it is adult stem cells that are already providing safe and effective therapies for patients now, without the problems of rejection or tumors," Prentice explains.

"We need to pour our resources, especially taxpayer dollars, into adult stem cell research to foster more and better treatments and put the patients first," he told LifeNews.com.

Levesque is a principal investigator for NeuroGeneration, a biotechnology company, and is affiliated with the UCLA School of Medicine and the Brain Research Institute.

Genetic Change Prevents Cell Death In Mouse Model Of Parkinson's Disease

ScienceDaily (Feb. 10, 2009) — By shifting a normal protective mechanism into overdrive, a University of Wisconsin-Madison scientist has completely shielded mice from a toxic chemical that would otherwise cause Parkinson's disease.

Parkinson's disease is a disabling and sometimes fatal disease that afflicts 1.5 million Americans, with about 60,000 new cases annually. Its major symptoms, including tremors and sluggish movement, have been traced to death of small numbers of nerve cells in the substantia nigra, a brain region that helps regulate movement.

Adding extra copies of a gene that makes a normal, protective protein neutralized a toxic chemical that would normally devastate the substantia nigra. "This complete abolition of toxicity was far greater than we expected," says Jeffrey Johnson, a UW-Madison professor of pharmacy. "It was striking. We thought we would see a 20 or 30 or 40 percent reduction in cell death."

The protective mechanism is initiated by a protein called Nrf-2, which is present in people and in mice, says Johnson. Nrf-2 (transcription factor NF-E2-related factor) is made by astrocytes, brain cells that play a supportive role to the neurons, which are the cells that actually carry nerve signals.

In recent years, researchers looking at a range of neurodegenerative diseases, including Alzheimer's and Lou Gehrig's diseases as well as Parkinson's, have focused on the astrocytes in their quest to help the brain protect itself from stressful conditions that are deadly to neurons. "Astrocytes way outnumber neurons and are found throughout the central nervous system," says Johnson. "Neurons have always gotten the Academy Awards, but astrocyte dysfunction is becoming a central theme in neurodegenerative disease. If we can figure out how to fix a sick astrocyte, or even prevent it from getting sick, that could offer profound protection against almost all neurodegenerative diseases."

Because neurons are impossible to replace, the present research focus in neurodegenerative disease is on preventing their death in the first place. Parkinson's disease can be treated for a time by replacing dopamine, the brain chemical made by the substantia nigra, but the treatment loses its efficacy over time.

In a study funded by the National Institute of Environmental Health Sciences and published in today's Proceedings of the National Academy of Sciences, Johnson and UW-Madison colleagues Pei-Chun Chen, Marcelo Vargas and Delinda Johnson studied mice with extra Nrf-2 genes. The astrocytes in these mice produced about twice the normal level of Nrf-2 protein.

The researchers then dosed the mice with MPTP, a chemical that kills neurons in the substantia nigra and has become the major mechanism for studying Parkinson's disease in mice. The toxicity of MPTP was discovered in 1982, when young drug users in California developed the classic symptoms of Parkinson's disease, a disease that usually strikes those over age 60. Researchers found that the synthetic heroin these people had used was contaminated with MPTP, and further studies showed that MPTP is highly toxic to nerve cells in the substantia nigra.

When astrocytes make Nrf-2, the protein attaches to their DNA, kick-starting activity in hundreds of genes that release chemicals that can protect nearby neurons from oxidation – a series of chemical reactions that can injure or kill cells. "The astrocytes are also probably sucking up the bad stuff, thereby reducing the oxidative environment and stress on the neurons," says Johnson, adding that his laboratory is trying to identify those specific protective chemicals.

Nobody can predict when a manipulation of Nrf-2 could reach clinical trials, which Johnson says are at the very least two years in the future. While these experiments altered the mouse cells with genetic engineering, human trials would probably use drugs to boost Nrf-2 production in astrocytes. Several labs, including Johnson's, are already searching for candidate drugs.

The stakes are high, Johnson says, because Nrf-2 also protects brain cells in models of such fatal brain diseases as Alzheimer's, ALS, and Huntington's disease.

Normally, neurons die in these neurodegenerative diseases to "commit suicide" through a process called programmed cell death. "Nrf-2 seems to rebalance the system," Johnson says, "in favor of what we call programmed cell life."

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Adapted from materials provided by University of Wisconsin-Madison.

Protein Shields Mice from Parkinson's

(Ivanhoe Newswire) -- If results of a new study conducted in mice can be applied to people, Parkinson's disease and other neurological conditions may have met their match.

Researchers from the University of Wisconsin-Madison have found boosting levels of the naturally occurring protein Nrf-2 completely shields mice from a chemical known to induce Parkinson's disease. The protein is made by brain cells called astrocytes, which researchers believe help support neurons, the cells that actually carry nerve signals. When neurons die, they cannot be replaced, which leads to the devastating effects of neurological conditions.

"Neurons have always gotten the Academy Awards, but astrocyte dysfunction is becoming a central theme in neurodegenerative disease," study author Jeffrey Johnson was quoted as saying. "If we can figure out how to fix a sick astrocyte, or even prevent it from getting sick, which could offer profound protection against almost all neurodegenerative diseases."

In this study, mice who were genetically engineering to have extra Nrf-2 genes produced about twice the normal level of Nrf-2. When researchers injected them with a chemical called MPTP, which is known to kill neurons and cause Parkinson's, the extra Nrf-2 was 100 percent effective in warding off the chemical.

Johnson says he and his colleagues expected to see some reduction in cell death due to the treatment, but were surprised at the totality of the results. "This complete abolition of toxicity was far greater than we expected. It was striking."

Tests in humans are still at least a couple of years away, but the researchers are already looking for candidate drugs that could boost Nrf-2 production in human astrocytes. If suitable drugs are found, it could mean effective treatments not only for Parkinson's disease, but also Alzheimer's disease, Huntington's disease, amyotrophic lateral sclerosis, and other conditions involving the brain.

SOURCE: Proceedings of the National Academy of Sciences, published online February 2, 2009