Posts tagged lysosome
Articles and news from the latest research reports.
Learning how the brain takes out its trash may help decode neurological diseases
Imagine that garbage haulers don’t exist. Slowly, the trash accumulates in our offices, our homes, it clogs the streets and damages our cars, causes illness and renders normal life impossible.
Garbage in the brain, in the form of dead cells, must also be removed before it accumulates, because it can cause both rare and common neurological diseases, such as Parkinson’s. Now, University of Michigan researchers are a leap closer to decoding the critical process of how the brain clears dead cells, said Haoxing Xu, associate professor in the U-M Department of Molecular, Cellular and Developmental Biology.
A new U-M study identified two critical components of this cell clearing process: an essential calcium channel protein, TRPML1, that helps the so-called garbage collecting cells, called microphages or microglia, to clear out the dead cells; and alipid molecule, which helps activate TRPML1 and the process that allows the microphages to remove these dead cells.
Moreover, the Xu lab identified a synthetic chemical compound that can activate TRPML1. Because this chemical compound ultimately helps activate this cell-clearing process, it provides a drug target that could help combat these neurological diseases.
"This is clearly a drug target," Xu said. "What this paper picks out is exactly what is going wrong in this process."
Scientists began by looking at a very rare neurodegenerative disease called Type IV Mucolipidosis, a childhood neurodegenerative disease characterized by multiple disabilities.
Xu’s group found that lack of TRPML1 function, which is the channel through which calcium is released from the lysosome—the cell’s recycling center—into the microphage cells, contributes to these neurodegenerative conditions. If this calcium channel doesn’t work, calcium cannot be released, and dead cells aren’t removed, Xu said. The synthetic chemical compound stimulates the TRPML1 calcium channel to release the calcium into the cell.
Further, dead cells “are bad for live cells,” Xu said. An excess of dead cells leads the macrophage cells to also kill healthy neurons necessary for neurological function, which in turn can lead to these neurodegenerative diseases.
There are many neurodegenerative diseases, some very rare and some more common, such as Parkinson’s and ALS. The common thread among them is the dearth of live and functioning neurons, which prevents the neurological system from carrying out normal functions, Xu said.
Thus, identifying a lipid molecule and also chemical compounds that stimulates proper function of the TRMPL1 function could revolutionize the treatment of these neurodegenerative diseases.
The next step in Xu’s research is to test how these general observations are helpful to the neurological diseases and whether the compound is effective in animal models of neurological diseases.
The paper, “A TRP channel in the lysosome regulates large particle phagocytosis via focal exocytosis,” appeared Aug. 29 online in Developmental Cell.
Parkinson’s Disease Protein Gums up Garbage Disposal System in Cells
Clumps of α-synuclein protein in nerve cells are hallmarks of many degenerative brain diseases, most notably Parkinson’s disease.
“No one has been able to determine if Lewy bodies and Lewy neurites, hallmark pathologies in Parkinson’s disease can be degraded,” says Virginia Lee, PhD, director of the Center for Neurodegenerative Disease Research, at the Perelman School of Medicine, University of Pennsylvania.
“With the new neuron model system of Parkinson’s disease pathologies our lab has developed recently, we demonstrated that these aberrant clumps in cells resist degradation as well as impair the function of the macroautophagy system, one of the major garbage disposal systems within the cell.”
Macroautophagy, literally self eating, is the degradation of unnecessary or dysfunctional cellular bits and pieces by a compartment in the cell called the lysosome.
Lee, also a professor of Pathology and Laboratory Medicine, and colleagues published their results in the early online edition of the Journal of Biological Chemistry this week.
Alpha-synuclein (α-syn ) diseases all have clumps of the protein and include Parkinson’s disease (PD), and array of related disorders: PD with dementia , dementia with Lewy bodies, and multiple system atrophy. In most of these, α-syn forms insoluble aggregates of stringy fibrils that accumulate in the cell body and extensions of neurons.
These unwanted α-syn clumps are modified by abnormal attachments of many phosphate chemical groups as well as by the protein ubiquitin, a molecular tag for degradation. They are widely distributed in the central nervous system, where they are associated with neuron loss.
Using cell models in which intracellular α-syn clumps accumulate after taking up synthetic α-syn fibrils, the team showed that α-syn inclusions cannot be degraded, even though they are located near the lysosome and the proteasome, another type of garbage disposal in the cell.
The α-syn aggregates persist even after soluble α-syn levels within the cell are substantially reduced, suggesting that once formed, the α-syn inclusions are resistant to being cleared. What’s more, they found that α-syn aggregates impair the overall autophagy degradative process by delaying the maturation of autophagy machines known as autophagosomes, which may contribute to the increased cell death seen in clump-filled nerve cells. Understanding the impact of α-syn aggregates on autophagy may help elucidate therapies for α-syn-related neurodegeneration.
(Source: uphs.upenn.edu)