Posts tagged phagocytosis
Articles and news from the latest research reports.
Protein that Causes Frontotemporal Dementia also Implicated in Alzheimer’s Disease
Researchers at the Gladstone Institutes have shown that low levels of the protein progranulin in the brain can increase the formation of amyloid-beta plaques (a hallmark of Alzheimer’s disease), cause neuroinflammation, and worsen memory deficits in a mouse model of this condition. Conversely, by using a gene therapy approach to elevate progranulin levels, scientists were able to prevent these abnormalities and block cell death in this model.
Progranulin deficiency is known to cause another neurodegenerative disorder, frontotemporal dementia (FTD), but its role in Alzheimer’s disease was previously unclear. Although the two conditions are similar, FTD is associated with greater injury to cells in the frontal cortex, causing behavioral and personality changes, whereas Alzheimer’s disease predominantly affects memory centers in the hippocampus and temporal cortex.
Earlier research showed that progranulin levels were elevated near plaques in the brains of patients with Alzheimer’s disease, but it was unknown whether this effect counteracted or exacerbated neurodegeneration. The new evidence, published today in Nature Medicine, shows that a reduction of the protein can severely aggravate symptoms, while increases in progranulin may be the brain’s attempt at fighting the inflammation associated with the disease.
According to first author S. Sakura Minami, PhD, a postdoctoral fellow at the Gladstone Institutes, “This is the first study providing evidence for a protective role of progranulin in Alzheimer’s disease. Prior research had shown a link between Alzheimer’s and progranulin, but the nature of the association was unclear. Our study demonstrates that progranulin deficiency may promote Alzheimer’s disease, with decreased levels rendering the brain vulnerable to amyloid-beta toxicity.”
In the study, the researchers manipulated several different mouse models of Alzheimer’s disease, genetically raising or lowering their progranulin levels. Reducing progranulin markedly increased amyloid-beta plaque deposits in the brain as well as memory impairments. Progranulin deficiency also triggered an over-active immune response in the brain, which can contribute to neurological disorders. In contrast, increasing progranulin levels via gene therapy effectively lowered amyloid beta levels, protecting against cell toxicity and reversing the cognitive deficits typically seen in these Alzheimer’s models.
These effects appear to be linked to progranulin’s involvement in phagocytosis, a type of cellular house-keeping whereby cells “eat” other dead cells, debris, and large molecules. Low levels of progranulin can impair this process, leading to increased amyloid beta deposition. Conversely, increasing progranulin levels enhanced phagocytosis, decreasing the plaque load and preventing neuron death.
“The profound protective effects of progranulin against both amyloid-beta deposits and cell toxicity have important therapeutic implications,” said senior author Li Gan, PhD, an associate investigator at Gladstone and associate professor of neurology at the University of California, San Francisco. “The next step will be to develop progranulin-enhancing approaches that can be used as potential novel treatments, not only for frontotemporal dementia, but also for Alzheimer’s disease.”
(Source: gladstoneinstitutes.org)
Microglia controls neuron production as brain develops
In a surprise breakthrough, researchers at the UC Davis MIND Institute and their colleagues have found that microglia remove healthy neural progenitor cells (NPCs) through phagocytosis to control neuron production during brain development. This newly discovered mechanism keeps neuron numbers in check, preventing brain overgrowth.
The discovery could open up new avenues for brain research and lead to therapies for a variety of neurological conditions.
The study was published online in the The Journal of Neuroscience.
Microglia are the immune component cell of the central nervous system. Similar to macrophages, microglia provide the brain’s primary defense against pathogens and foreign bodies, clear away dying cells and help repair neural damage. When inactive, they act as sentinels. When a problem is located, they activate and eliminate it. However, until recently, no one had realized the important roles they play in brain development.
"We have known for some time that neurons can undergo apoptosis, a form of cell death, and ultimately be removed by microglia," said Stephen Noctor, assistant professor in the Department of Psychiatry and Behavioral Sciences and the study’s lead author. "But this is new. Microglia are actually eating healthy progenitor cells, thereby regulating the number of neurons produced in the developing brain."
During development, NPCs produce neurons in the brain’s proliferative zones. However, creating too many or too few neurons can have dire consequences.
"If you have too many cells, there’s only so much trophic support (brain infrastructure for cell growth and survival) to keep neurons alive," Noctor said. "All these cells competing for resources could easily throw off connectional properties, altering the way surviving neurons interact. Likewise, having too few cortical cells would have profoundly negative consequences."
(Image: Antoine Triller, Alain Bessis & Serge Marty - Département de Biologie, ENS)
Specific protein essential for healthy eyes
Researchers at the Hebrew University of Jerusalem, in collaboration with researchers at the Salk Institute in California, have found for the first time that a specific protein is essential not only for maintaining a healthy retina in the eye, but also may have implications for understanding and possibly treating other conditions in the immune, reproductive, vascular and nervous systems, as well as in various cancers.
Their work, reported online in the journal Neuron, highlights the role of Protein S in the maintenance of a healthy retina through its involvement in the process of pruning photoreceptors, the light-sensitive neurons in the eye. (This process is also referred to as phagocytosis.) These photoreceptors keep growing and elongating from their inner end. In order to maintain a constant length, they must be pruned from their outer end by specialized cells called retinal pigment epithelial cells.
Without such pruning — which also clears away many free radicals and toxic by-products generated during visual biochemical reactions — photoreceptors would succumb to toxicity and degenerate, leading if unchecked to blindness. A receptor molecule called Mer is a key in photoreceptor pruning, and is therefore vital for retinal health. Mutations in the mouse, rat and human Mer genes cause retinal degeneration, which finally leads to blindness.
The Hebrew University study published in Neuron focuses on the molecules activating Mer in this pruning mechanism. Although two such molecules – Gas6 and Protein S — were identified previously, it was yet to be proven that they also play a role in a living organism. To show this, Dr. Tal Burstyn-Cohen of the Hebrew University Institute of Dental Sciences and colleagues at the Salk Institute in California found in their experiments on laboratory animals that both Gas6 and Protein S are needed to activate phagocytosis, or pruning, of retinal photoreceptors, and thus keep a healthy retina.
These findings could have practical implications, since Protein S also functions as a potent blood anticoagulant. People with Protein S deficiency are at risk for life threatening thrombosis (blood clots) and thromboembolism (a clot that breaks loose and is carried by the blood stream to plug another vessel).
These results further open new avenues of research into the role of Protein S in activating the receptors in other tissues where their function was shown to be important, such as in the immune, reproductive, vascular and nervous systems, as well as in various cancers where activation of receptors has been observed. For example, since Protein S is important for blood vessel formation, neutralizing Protein S in the blood vessels supplying blood to cancer growths could interfere with the cancerous blood supply.
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