Posts tagged precursor cells
Articles and news from the latest research reports.
Attractants prevent nerve cell migration
A vision is to implant nerve precursor cells in the diseased brains of patients with Parkinson’s and Huntington’s diseases, whereby these cells are to assume the function of the cells that have died off. However, the implanted nerve cells frequently do not migrate as hoped, rather they hardly move from the site. Scientists at the Institute for Reconstructive Neurobiology at Bonn University have now discovered an important cause of this: Attractants secreted by the precursor cells prevent the maturing nerve cells from migrating into the brain. The results are presented in the journal “Nature Neuroscience.”
One approach for treating patients with Parkinson’s or Huntington’s disease is to replace defective brain cells with fresh cells. To do this, immature precursor cells from neurons are implanted into the diseased brains; these cells are to then mature on-site and take over the function of the defective cells. “However, it has been shown again and again that the nerve cells generated by the transplant barely migrate into the brain but remain largely confined to the implant site,” says Prof. Dr. Oliver Brüstle, Director of the Institute for Reconstructive Neurobiology at Bonn University. Scientists have believed for a long time that this effect is associated with the fact that in the mature brain, there are unfavorable conditions for the uptake of additional nerve cells.
Immature and more mature nerve cells attract each other like magnets
The researchers from the Institute for Reconstructive Neurobiology of Bonn University have now discovered a fully unexpected mechanism to which the deficient migratory behavior of the graft-derived neurons can be attributed. The implanted cells mature at different rates and thus there is a mixture of the two stages. “Like magnets, the precursor cells which are still largely immature attract the nerve cells which have already matured further, which is why there is a sort of agglomeration,” says lead author Dr. Julia Ladewig, who was recently awarded a research prize of 1.25 million Euro by the North Rhine-Westphalian Stem Cell Network, which is supported by State Ministry of Science and Research.
The cause of the attractive force which has remained hidden to date involves chemical attractants which are secreted by the precursor cells. “In this way, the nerve precursor cells prevent the mature brain cells from penetrating further into the tissue,” says Dr. Philipp Koch, who performed the primary work for the study as an additional lead author, together with Dr. Ladewig.
The scientists had initially observed that, the more precursor cells contained in the transplant, the worse the migration of nerve cells is. In a second step, the researchers from the Institute for Reconstructive Neurobiology at Bonn University were able to decode and inactivate the attractants responsible for the agglomeration of mature and immature neurons. When the scientists deactivated the receptor tyrosine kinase ligands FGF2 and VEGF with inhibitors, mature nerve cells migrated better into the animal brains and dispersed over much larger areas.
Promising universal approach for transplants
“This is a promising new approach to solve an old problem in neurotransplantation,” Prof. Brüstle summarizes. Through the inhibition of attractants, the migration of implanted nerve precursor cells into the brain can be significantly improved. As the researchers have shown in various models with precursor cells from animals and humans, the mechanism is a fundamental principle which also functions across species. “However, more research is still needed to transfer the principle into clinical application,” says Prof. Brüstle.
(Source: www3.uni-bonn.de)
Serotonin Mediates Exercise-Induced Generation of New Neurons
Mice that exercise in running wheels exhibit increased neurogenesis in the brain. Crucial to this process is serotonin signaling. These are the findings of a study by Dr. Friederike Klempin, Daniel Beis and Dr. Natalia Alenina from the research group led by Professor Michael Bader at the Max Delbrück Center (MDC) Berlin-Buch. Surprisingly, mice lacking brain serotonin due to a genetic mutation exhibited normal baseline neurogenesis. However, in these serotonin-deficient mice, activity-induced proliferation was impaired, and wheel running did not induce increased generation of new neurons. (Journal of Neuroscience)
Scientists have known for some time that exercise induces neurogenesis in a specific brain region, the hippocampus. However, until this study, the underlying mechanism was not fully understood. The hippocampus plays an important role in learning and in memory and is one of the brain regions where new neurons are generated throughout life.
Serotonin facilitates precursor cell maturation
The researchers demonstrated that mice with the ability to produce serotonin are likely to release more of this hormone during exercise, which in turn increases cell proliferation of precursor cells in the hippocampus. Furthermore, serotonin seems to facilitate the transition of stem to progenitor cells that become neurons in the adult mouse brain.
For Dr. Klempin and Dr. Alenina it was surprising that normal baseline neurogenesis occurs in mice that, due to a genetic mutation, cannot produce serotonin in the brain. However, they noted that some of the stem cells in serotonin-deficient mice either die or fail to become neurons.
Yet, these animals seem to have a mechanism that allows compensation for the deficit, in that progenitor cells, an intermediate stage in the development from a stem cell to a neuron, divide more frequently. According to the researchers, this is to maintain the pool of these cells.
However, the group of wheel-running mice that do not produce serotonin did not exhibit an exercise-induced increase in neurogenesis. The compensatory mechanism failed following running. The researchers concluded: “Serotonin is not necessarily required for baseline generation of new neurons in the adult brain, but is essential for exercise-induced hippocampal neurogenesis.”
Hope for new approaches to treat depression and memory loss in the elderly
Deficiency in serotonin, popularly known as the “molecule of happiness”, has been considered in the context of theories linking major depression to declining neurogenesis in the adult brain. “Our findings could potentially help to develop new approaches to prevent and treat depression as well as age-related decline in learning and memory,” said Dr. Klempin and Dr. Alenina.
Researchers Discover Dynamic Behavior Of Progenitor Cells In Brain
By monitoring the behavior of a class of cells in the brains of living mice, neuroscientists at Johns Hopkins discovered that these cells remain highly dynamic in the adult brain, where they transform into cells that insulate nerve fibers and help form scars that aid in tissue repair.
Published online April 28 in the journal Nature Neuroscience, their work sheds light on how these multipurpose cells communicate with each other to maintain a highly regular, grid-like distribution throughout the brain and spinal cord. The disappearance of one of these so-called progenitor cells causes a neighbor to quickly divide to form a replacement, ensuring that cell loss and cell addition are kept in balance.
“There is a widely held misconception that the adult nervous system is static or fixed, and has a limited capacity for repair and regeneration,” says Dwight Bergles, Ph.D., professor of neuroscience and otolaryngology at the Johns Hopkins University School of Medicine. “But we found that these progenitor cells, called oligodendrocyte precursor cells (OPCs), are remarkably dynamic. Unlike most other adult brain cells, they are able to respond to the repair needs around them while maintaining their numbers.”
OPCs can mature to become oligodendrocytes — support cells in the brain and spinal cord responsible for wrapping nerve fibers to create insulation known as myelin. Without myelin, the electrical signals sent by neurons travel poorly and some cells die due to the lack of metabolic support from oligodendrocytes. It is the death of oligodendrocytes and the subsequent loss of myelin that leads to neurological disability in diseases such as multiple sclerosis.
During brain development, OPCs spread throughout the central nervous system and make large numbers of oligodendrocytes. Scientists know that few new oligodendrocytes are born in the healthy adult brain, yet the brain is flush with OPCs. However, the function of OPCs in the adult brain wasn’t clear.
To find out, Bergles and his team genetically modified mice so that their OPCs contained a fluorescent protein along their edges, giving crisp definition to their many fine branches that extend in every direction. Using special microscopes that allow imaging deep inside the brain, the team watched the activity of individual cells in living mice for over a month.
The researchers discovered that, far from being static, the OPCs were continuously moving through the brain tissue, extending their “tentacles” and repositioning themselves. Even though these progenitors are dynamic, each cell maintains its own area by repelling other OPCs when they come in contact.
“The cells seem to sense each other’s presence and know how to control the number of cells in their population,” says Bergles. “It looks like this process goes wrong in multiple sclerosis lesions, where there are reduced numbers of OPCs, a loss that may impair the cells’ ability to sense whether demyelination has occurred. We don’t yet know what molecules are involved in this process, but it’s something we’re actively working on.”
To see if OPCs do more than form new oligodendrocytes in the adult brain, the team tested their response to injury by using a laser to create a small wound in the brain. Surprisingly, OPCs migrated to the injury site and contributed to scar formation, a previously unsuspected role. The empty space in the OPC grid, created by the loss of the scar-forming OPCs, was then filled by cell division of neighboring OPCs, providing an explanation for why brain injury is often accompanied by proliferation of these cells.
“Scar cells are not oligodendrocytes, so the term ‘oligodendrocyte precursor cell’ may now be outdated,” says Bergles. “These cells are likely to have a broader role in tissue regeneration and repair than we thought. Because traumatic brain injuries, multiple sclerosis and other neurodegenerative diseases require tissue regeneration, we are eager to learn more about the functions of these enigmatic cells.”