Parkinson gene: Nerve growth factor halts mitochondrial degeneration

Neurodegenerative diseases like Parkinson’s disease involve the death of thousands of neurons in the brain. Nerve growth factors produced by the body, such as GDNF, promote the survival of the neurons; however, clinical tests with GDNF have not yielded in any clear improvements. Scientists from the Max Planck Institute of Neurobiology in Martinsried and their colleagues have now succeeded in demonstrating that GDNF and its receptor Ret also promote the survival of mitochondria, the power plants of the cell. By activating the Ret receptor, the scientists were able to prevent in flies and human cell cultures the degeneration of mitochondria, which is caused by a gene defect related to Parkinson’s disease. This important new link could lead to the development of more refined GDNF therapies in the future.

In his “Essay on the Shaking Palsy” of 1817, James Parkinson provided the first description of a disease that today affects almost 280,000 people in Germany. The most conspicuous symptom of Parkinson’s disease is a slow tremor, which is usually accompanied by an increasing lack of mobility and movement in the entire body. These symptoms are visible manifestations of a dramatic change that takes place in the brain: the death of large numbers of neurons in the Substantia nigra of the midbrain.

Despite almost 200 years of research into Parkinson’s, its causes have not yet been fully explained. It appears to be certain that, in addition to environmental factors, genetic mutations also play a role in the emergence of the disease. A series of genes is now associated with Parkinson’s disease. One of these is PINK1, whose mutation causes mitochondrial dysfunction. Mitochondria are a cell’s power plants and without them, a cell cannot function properly or regenerate. Scientists from the Max Planck Institute of Neurobiology and their colleagues from Munich and Martinsried have now discovered a hitherto unknown link that counteracts mitochondrial dysfunction in the case of a PINK1 mutation.

The PINK1 gene emerged at a very early stage in evolutionary history and exists in a similar form for example in humans, mice and flies. In the fruit fly Drosophila, a mitochondrial defect triggered by a PINK1 mutation manifests in the fraying of the muscles. Less visible, the flies’ neurons also die. The scientists studied the molecular processes involved in these changes and discovered that the activation of the Ret receptor counteracts the muscle degeneration. “This is a really interesting finding which links the mitochondrial degeneration in Parkinson’s disease with nerve growth factors,” reports Rüdiger Klein, the head of the research study. Ret is not an unknown factor for the Martinsried-based neurobiologists: “We already succeeded in demonstrating a few years ago in mice that neurons without the Ret receptor die prematurely and in greater numbers with increasing age,” says Klein.

The Ret receptor is the cells’ docking site for the growth factor GDNF, which is produced by the body. Various studies carried out in previous years showed that the binding of GDNF to its Ret receptor can prevent the early death of neurons in the Substantia nigra. However, clinical studies on the influence of GDNF on the progression of Parkinson’s in patients did not lead to any clear improvement in their condition.

The new findings from basic research suggest that the mitochondrial metabolism is boosted or re-established through Ret/GNDF. “Based on this finding, existing therapies could be refined or tailored to specific patient groups,” hopes Pontus Klein, who conducted the study within the framework of his doctoral thesis. This hope does not appear to be completely unfounded: The scientists have already discovered a Ret/GDNF effect in human cells with a PINK1 defect similar to that observed in the fruit fly. It may therefore be possible to search for metabolic defects in the mitochondria of Parkinson’s patients in future. A specially tailored GDNF therapy could then provide a new therapeutic approach for patients who test positively.

Engineered stem cell advance points toward treatment for ALS

Transplantation of human stem cells in an experiment conducted at the University of Wisconsin-Madison improved survival and muscle function in rats used to model ALS, a nerve disease that destroys nerve control of muscles, causing death by respiratory failure.

ALS (amyotrophic lateral sclerosis) is sometimes called “Lou Gehrig’s disease.” According to the ALS Association, the condition strikes about 5,600 Americans each year. Only about half of patients are alive three years after diagnosis. 

In work recently completed at the UW School of Veterinary Medicine, Masatoshi Suzuki, an assistant professor of comparative biosciences, and his colleagues used adult stem cells from human bone marrow and genetically engineered the cells to produce compounds called growth factors that can support damaged nerve cells.

The researchers then implanted the cells directly into the muscles of rats that were genetically modified to have symptoms and nerve damage resembling ALS.

In people, the motor neurons that trigger contraction of leg muscles are up to three feet long. These nerve cells are often the first to suffer damage in ALS, but it’s unclear where the deterioration begins. Many scientists have focused on the closer end of the neuron, at the spinal cord, but Suzuki observes that the distant end, where the nerve touches and activates the muscle, is often damaged early in the disease.

The connection between the neuron and the muscle, called the neuro-muscular junction, is where Suzuki focuses his attention. “This is one of our primary differences,” Suzuki says. “We know that the neuro-muscular junction is a site of early deterioration, and we suspected that it might be the villain in causing the nerve cell to die. It might not be an innocent victim of damage that starts elsewhere.”

Previously, Suzuki found that injecting glial cell line-derived neurotropic factor (GDNF) at the junction helped the neurons survive. The new study, published in the journal Molecular Therapy on May 28, expands the research to show a similar effect from a second compound, called vascular endothelial growth factor.

In the study, Suzuki found that using stem cells to deliver vascular endothelial growth factor alone improved survival and delayed the onset of disease and the decline in muscle function. That result mirrored his earlier study with GDNF.

But the real advance, Suzuki says, was finding an even better result from using stem cells that create both of these two growth factors. “In terms of disease-free time, overall survival, and sustaining muscle function, we found that delivering the combination was more powerful than either growth factor alone. The results would provide a new hope for people with this terrible disease.”

The new research was supported by the ALS Association, the National Institutes of Health, the University of Wisconsin Foundation, and other groups. 

The injected stem cells survived for at least nine weeks, but did not become neurons. Instead, their contribution was to secrete one or both growth factors. 

Originally, much of the enthusiasm for stem cells focused on the hope of replacing damaged cells, but Suzuki’s approach is different. “These motor nerve cells have extremely long connections, and replacing these cells is still challenging. But we aim to keep the neurons alive and healthy using the same growth factors that the body creates, and that’s what we have shown here.”

For the test, Suzuki used ALS model rats with a mutation that is found in a small percentage of ALS patients who have a genetic form of the disease. “This model has been accepted as the best test bed for ALS experiments,” says Suzuki. 

By using adult mesenchymal stem cells, the technique avoided the danger of tumor that can arise with the transplant of embryonic stem cells and related “do-anything” cells.  Importantly, mesenchymal stem cells have been already used in clinical trials for various human diseases.

In the future, Suzuki hopes to apply his approach by using clinical grade stem cells. “Because this is a fatal and untreatable disease, we hope this could enter a clinical trial relatively soon.”