Monthly Archives: januar 2017

A Japanese research team has found that collapse of the Mitochondria-Associated Membrane (MAM) is a common pathological hallmark to two distinct inherited forms of ALS: SOD1- and SIGMAR1-linked ALS. The research findings were reported in EMBO Molecular Medicine.

Recent studies have revealed that the MAM plays a key role in cellular homeostasis, such as lipid synthesis, protein degradation, and energy metabolism. Intriguingly, a recessive mutation in SIGMAR1 gene, which encodes sigma 1 receptor (Sig1R), a chaperone enriched in the MAM, is causative for a juvenile ALS. In this study, the researchers identified a novel ALS-linked SIGMAR1 mutation, c.283dupC/p.L95fs in a juvenile-onset ALS case. Moreover, ALS-linked Sig1R mutant proteins were unstable and non-functional, indicating a loss-of function mechanism in SIGMAR1-linked ALS.

A loss of Sig1R function induced MAM disruption in neurons. However, it was still unknown whether the MAM alternation was also involved in the other ALS cases. To address this question, the researchers cross-bred SIGMAR1 deficient mice with the other inherited ALS mice which overexpress a mutant form of SOD1 gene. SIGMAR1 deficiency accelerated disease onset of SOD1-ALS mice by more than 20%. In those mice, inositol triphosphate receptor type-3 (IP3R3), a MAM-enriched calcium ion (Ca2+) channel, was disappeared from the MAM. The loss of proper localization of IP3R3 led to Ca2++ dysregulation to exacerbate the neurodegeneration. The researchers also found that IP3R3 was selectively enriched in motor neurons, suggesting that integrity of the MAM is crucial for the selective vulnerability in ALS.

These results provide new perspectives regarding future therapeutics, especially focused on preventing the MAM disruption for ALS patients. Together with the research from other groups, collapse of the MAM is widely observed in the other genetic causes of ALS, and therefore it may be applicable to sporadic ALS patients.

Paper: “Mitochondria-associated membrane collapse is a common pathomechanism in SIGMAR1- and SOD1-linked ALS”

Reprinted from materials provided by Nagoya University.

Drug researchers have identified several new biological markers to measure the progression of the inherited neurodegenerative disorder Huntington’s disease (HD). Their findings, published in the Journal of Experimental Medicine, could benefit clinical trials that test new treatments for the disease.

One of the earliest events in HD is that mutant huntingtin aggregates disrupt the function of mitochondria, lowering cellular energy levels and causing oxidative damage. The researchers set out to identify markers of HD in non-neural tissues that could be used to track the progression of the disease and its response to P110 or other candidate drugs.

The team found that the levels of mitochondrial DNA, presumably released from dying neurons, were increased in the blood plasma of mice that were starting to develop the symptoms of HD. In contrast, mitochondrial DNA levels decreased at later stages of the disease. P110 treatment corrected plasma mitochondrial DNA back to the levels seen in healthy mice.

The researchers identified several other potential biomarkers that were elevated in HD model mice, including the levels of 8-hydroxy-deoxy-guanosine, a product of oxidative DNA damage, in the urine and the presence of mutant huntingtin aggregates and oxidative damage in muscle and skin cells. The levels of each of these biomarkers were reduced by P110 treatment.

It remains to be seen whether all of these biomarkers are reliable indicators of HD in humans. The team found, however, that mitochondrial DNA levels were significantly elevated in plasma samples from a small number of HD patients.

Paper: “Potential biomarkers to follow the progression and treatment response of Huntington’s disease”
Reprinted from materials provided by Rockefeller University Press.

Researchers have shed new light on the nerve cell processes that lead to Alzheimer’s disease, overturning previously held ideas of how the disease develops and opening the door to new treatment options that could halt or slow its progression.

The study was published in the journal Science.

Studying human brain tissue, the research team identified a protein, kinase p38γ, that is lost as AD progresses. When they reintroduced the protein into the brains of mice, it was shown to have a protective effect against memory deficits associated with the disease.

Two of the hallmarks of Alzheimer’s are the presence of protein plaques (made up of amyloid-beta) and tangles (made up of tau protein) in the brain. The accumulation of these plaques and tangles is associated with cell death, brain atrophy and memory loss.

The research team revealed that a crucial step in the process that leads to tangles has been misunderstood. Previously, scientists believed the plaque-forming protein, amyloid-beta, caused a modification – called phosphorylation – to the tau protein resulting in cell death and, ultimately, Alzheimer’s disease. Increased phosphorylation of tau eventually leads to its accumulation as tangles.

Results from the new study suggest that the phosphorylation of tau initially has a protective effect on neurons, and that amyloid-beta assaults the protective functionality until it is progressively lost. This is the stage at which toxicity levels cause the destruction of neurons and results in the cognitive deficits associated with Alzheimer’s disease.

The study used different mice models and human brain tissue from the Sydney Brain Bank to identify a protein called kinase p38γ, which assisted the protective phosphorylation of tau and interfered with the toxicity created by amyloid-beta.

The next step for the researchers will be to develop their patented discoveries into a novel treatment for humans.

Paper: Site-specific phosphorylation of tau inhibits amyloid-β toxicity in Alzheimer’s mice”
Reprinted from materials provided by the University of New South Wales.