 |
|
Reduced insulin in the brain triggers Alzheimer's degeneration
March 23, 2006Neuroendocrine disorder distinct from other types of diabetes
Providence, RI - By depleting insulin and its related proteins in the brain, researchers at Rhode Island Hospital and Brown Medical School have replicated the progression of Alzheimer's disease - including plaque deposits, neurofibrillary tangles, impaired cognitive functioning, cell loss and overall brain deterioration - in an experimental animal model. The study demonstrates that Alzheimer's is a brain-specific neuroendocrine disorder, distinct from other types of diabetes.
In the study, brain deterioration was not related to the pancreas, which regulates insulin for the body. When pancreatic insulin is deficient or the body fails to respond to it, the result is Type 1 or Type 2 diabetes. Previous work by the researchers with postmortem brain tissue of Alzheimer's patients showed a strong link between insulin depletion in the brain and Alzheimer's disease, raising the possibility that Alzheimer's is a neuroendocrine disorder, or a Type 3 diabetes.
"We have demonstrated that a loss of insulin in the brain triggers the onset of Alzheimer's, probably because as the brain loses insulin, the cells that require insulin to function and survive also eventually die. The consequences are increased oxidative stress, brain deterioration, loss of cognitive function, and a buildup of plaques and tangles in the brain - all hallmarks of Alzheimer's, says senior author Suzanne M. de la Monte, MD, MPH, a neuropathologist at Rhode Island Hospital and a professor of pathology and clinical neuroscience at Brown Medical School in Providence, RI.
"We now know that if you specifically target insulin and its actions in the brain, you could develop new treatments for this disease," de la Monte says.
The study is published in the current issue (Volume 9, Issue 1) of the Journal of Alzheimer's Disease (http://www.j-alz.com).
Researchers injected the brains of rats with Streptozotocin (STZ), a compound that when metabolized, destroys beta cells in pancreatic islets and produces diabetes. When injected directly into the brain, the treatment caused neurodegeneration, while the pancreatic islet cells remained intact. That is because insulin depletion produced by STZ was confined to the brain, just like what occurs in most cases of Alzheimer's.
"This study provides definitive evidence that impairments in insulin/IGF signaling and deficiencies in the corresponding growth factors can occur in the central nervous system (CNS) independent of Type 1 or Type 2 diabetes," the authors write.
As a result of the treatment, insulin and its IGF-I receptors were significantly reduced in the brain, triggering a cascade of neurodegeneration. Both insulin and IGF-I activate complex signaling pathways downstream, prompting energy metabolism and growth required for learning and memory, and inhibition of oxidative stress, which unchecked could trigger neurodegeneration. As insulin was depleted, neurons died and the brain dropped to half its size, a result of atrophy which is a prominent feature of Alzheimer's. At the same time, there was an increase in astrocytes and microglial cells, which are responsible for neuroinflammation, another critical and consistent feature of Alzheimer's and probably related to the increased amyloid deposition in the brain, the researchers say.
Also, there was increased activation of a kinase called GSK-3 beta. This kinase is overactive in Alzheimer's and triggers tau phosphorylation, which is known to be at the core of neurofibrillary tangles. The researchers had previously shown that tau is regulated by insulin and insulin-like growth factor (IGF-I). In the current research, they found that as insulin and IGF-I were depleted in the brain, the expression of GSK-3 beta increased, leading to oxidative stress and cell death.
While the link between insulin and tau had been established, researchers also looked at the connection between insulin and amyloid precursor protein gene expression, as increased levels could account for amyloid accumulation, or the buildup of plaques in the brain. They found that amyloid beta deposits in vessels and plaques did build up in the brain, and they suggest that these abnormalities occurred due to increased oxidative stress.
Another feature of Alzheimer's affected by impaired insulin signaling, acetylcholine deficiency, is linked to dementia and has long recognized as an early abnormality in Alzheimer's. The enzyme that makes acetylcholine, choline acetyltransferase (ChAT), was previously found to be regulated by insulin and IGF-1. In brains with Alzheimer's, impairment of insulin and IGF-I signaling mechanisms correlate with deficits in acetylcholine production. In this study, ChAT was markedly reduced in the experimental Alzheimer's model.
"Our previous work has shown that many of the important features of Alzheimer's - such as the accumulation of phosphorylated tau and the death of neurons - were somehow linked to insulin deficiency in the brain. This study shows that insulin is the controlling factor in all of these features of Alzheimer's disease," de la Monte says.
"The evidence suggests that impaired insulin and IGF signaling must be addressed in order to make significant progress in the treatment and prevention of Alzheimer's disease,\\\
Lifespan
"We have demonstrated that a loss of insulin in the brain triggers the onset of Alzheimer's, probably because as the brain loses insulin, the cells that require insulin to function and survive also eventually die. The consequences are increased oxidative stress, brain deterioration, loss of cognitive function, and a buildup of plaques and tangles in the brain - all hallmarks of Alzheimer's, says senior author Suzanne M. de la Monte, MD, MPH, a neuropathologist at Rhode Island Hospital and a professor of pathology and clinical neuroscience at Brown Medical School in Providence, RI.
"We now know that if you specifically target insulin and its actions in the brain, you could develop new treatments for this disease," de la Monte says.
The study is published in the current issue (Volume 9, Issue 1) of the Journal of Alzheimer's Disease (http://www.j-alz.com).
Researchers injected the brains of rats with Streptozotocin (STZ), a compound that when metabolized, destroys beta cells in pancreatic islets and produces diabetes. When injected directly into the brain, the treatment caused neurodegeneration, while the pancreatic islet cells remained intact. That is because insulin depletion produced by STZ was confined to the brain, just like what occurs in most cases of Alzheimer's.
"This study provides definitive evidence that impairments in insulin/IGF signaling and deficiencies in the corresponding growth factors can occur in the central nervous system (CNS) independent of Type 1 or Type 2 diabetes," the authors write.
As a result of the treatment, insulin and its IGF-I receptors were significantly reduced in the brain, triggering a cascade of neurodegeneration. Both insulin and IGF-I activate complex signaling pathways downstream, prompting energy metabolism and growth required for learning and memory, and inhibition of oxidative stress, which unchecked could trigger neurodegeneration. As insulin was depleted, neurons died and the brain dropped to half its size, a result of atrophy which is a prominent feature of Alzheimer's. At the same time, there was an increase in astrocytes and microglial cells, which are responsible for neuroinflammation, another critical and consistent feature of Alzheimer's and probably related to the increased amyloid deposition in the brain, the researchers say.
Also, there was increased activation of a kinase called GSK-3 beta. This kinase is overactive in Alzheimer's and triggers tau phosphorylation, which is known to be at the core of neurofibrillary tangles. The researchers had previously shown that tau is regulated by insulin and insulin-like growth factor (IGF-I). In the current research, they found that as insulin and IGF-I were depleted in the brain, the expression of GSK-3 beta increased, leading to oxidative stress and cell death.
While the link between insulin and tau had been established, researchers also looked at the connection between insulin and amyloid precursor protein gene expression, as increased levels could account for amyloid accumulation, or the buildup of plaques in the brain. They found that amyloid beta deposits in vessels and plaques did build up in the brain, and they suggest that these abnormalities occurred due to increased oxidative stress.
Another feature of Alzheimer's affected by impaired insulin signaling, acetylcholine deficiency, is linked to dementia and has long recognized as an early abnormality in Alzheimer's. The enzyme that makes acetylcholine, choline acetyltransferase (ChAT), was previously found to be regulated by insulin and IGF-1. In brains with Alzheimer's, impairment of insulin and IGF-I signaling mechanisms correlate with deficits in acetylcholine production. In this study, ChAT was markedly reduced in the experimental Alzheimer's model.
"Our previous work has shown that many of the important features of Alzheimer's - such as the accumulation of phosphorylated tau and the death of neurons - were somehow linked to insulin deficiency in the brain. This study shows that insulin is the controlling factor in all of these features of Alzheimer's disease," de la Monte says.
"The evidence suggests that impaired insulin and IGF signaling must be addressed in order to make significant progress in the treatment and prevention of Alzheimer's disease,\\\
Lifespan
More Alzheimer Degeneration News Articles
 | Molecular and Cellular Biology of Neuroprotection in the CNS (Advances in Experimental Medicine and Biology) Given the very limited capacity of regeneration in the brain, protecting neurons that are on the brink of death is a major challenge for basic and clinical neuroscience, with implications for a broad spectrum of acute and chronic neurological and psychiatric diseases. This book brings together leading experts from neurobiology, neurophysiology, neuropharmacology, neuroimmunology and clinical... |
 | Neurodegenerative Disorders: Loss of Function Through Gain of Function (Research and Perspectives in Alzheimer's Disease) The main message from this book is that the different protein aggregation processes may all be amenable to a small number of intervention steps based on a common theme of the modulation of production, turnover and deposition of the corresponding disease gene products. The next few years will prove critical in evaluation the possibilities of rational therapeutic strategies towards regaining the... |
| The current status of the calcium hypothesis of brain aging and Alzheimer's disease: October 23-25, 1995 held at Ruprecht-Karls University, Heidelberg ... of Sciences workshop (CNS drug reviews) by T. C. G Smith | |
 | Distinct patterns of olfactory impairment in Alzheimer's disease, semantic dementia, frontotemporal dementia, and corticobasal degeneration [An article from: Neuropsychologia] by S. Luzzi, J.S. Snowden, D. Neary, M. Coccia, Provi This digital document is a journal article from Neuropsychologia, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.Description: Performance on tests of odour discrimination, naming, and matching was compared in patients with four distinct forms of... |
| International Conference on Frontal Lobe Degeneration of Non-Alzheimer Type (Dementia) | |
| Apolipoprotein E and presenilin-1 allelic variation and Alzheimer's disease in India.: An article from: Human Biology by G.R. Chandak, M. Uma Sridevi, C.J. Vas, D.M. Panikker, L. Singh This digital document is an article from Human Biology, published by Wayne State University Press on October 1, 2002. The length of the article is 5027 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser.From the author: ... | |
| Disappearance of memory fragments in patients with Alzheimer's disease: Evidence from a longitudinal study of visual priming [An article from: Neuropsychologia] by H. Mochizuki-Kawai, S. Mochizuki, A. Midorikawa, Y This digital document is a journal article from Neuropsychologia, published by Elsevier in . The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.Description: Previous studies suggested that perceptual memory as indexed by visual priming is normal in patients with Alzheimer's disease (AD).... |
| Memories are made of this. (nerve cells, includes related article on Alzheimer's disease): An article from: FDA Consumer by Ken Flieger This digital document is an article from FDA Consumer, published by U.S. Government Printing Office on September 1, 1989. The length of the article is 2183 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser.Citation... | |
| Senile Neurodegeneration and Neurotransmitters: Proceedings of the Seventh Workshop on Neurotransmitters and Diseases, Tokyo, June 16, 1990 (International Congress Series) by Japan) Workshop on Neurotransmitters and Diseases 1990 (Tokyo | |
 | Neurodegenerative Diseases: From Molecular Concepts to Therapeutic Targets |
| © 2008 BrightSurf.com |