News Release

Inactivation of Alzheimer's disease genes in mice causes dementia and brain degeneration

Peer-Reviewed Publication

Cell Press



Using advanced genetic engineering technology, scientists have discovered that deletion of two related genes linked to inherited forms of Alzheimer's disease causes memory loss and gradual death of nerve cells in the mouse brain. The researchers identified the molecular pathways through which inactivation of these genes in mice produces abnormalities strikingly reminiscent of Alzheimer's disease. The study, reported online in Neuron, may provide a new way to look at the cause of Alzheimer's disease, as it shows that the protein products of these Alzheimer's disease genes are essential for normal learning, memory and nerve cell survival. Furthermore, these results suggest that current therapeutic avenues of research designed to block the function of these genes may actually be detrimental.

Alzheimer's disease is a debilitating illness affecting 5 million Americans, with annual health care cost in excess of $100 billion. Mutations in the presenilin genes are the major cause of early onset, inherited forms of Alzheimer's disease (hence designated as "pre-senile" genes), but how these mutations cause the disease has not been clear. Since presenilins are involved in the production of amyloid peptides, the major components of amyloid plaques in the Alzheimer's disease brain, it was generally believed that genetic alterations in presenilins cause the disease by increasing brain levels of the particularly toxic form of amyloid peptides. Identification of compounds that can block presenilin function, therefore, has been a major therapeutic effort for combating Alzheimer's disease.



The research team, led by Dr. Jie Shen of Brigham and Women's Hospital and Harvard Medical School, created a unique mouse model that allowed them to examine the consequences of blocking presenilin function in the adult brain. Surprisingly, although the production of amyloid peptides was markedly reduced, these mutant mice nevertheless developed severe dementia and progressive brain degeneration that resembled the effects of Alzheimer's disease. Interestingly, nerve cell death was preceded by mild memory defects and abnormalities in specific cellular and molecular processes necessary for normal learning and memory, suggesting that these early changes may lead over time to brain degeneration. These results also caution that experimental drugs designed to block presenilin function, and thereby reduce amyloid production, may actually worsen the ongoing memory loss and neurodegeneration. According to Dr. Shen, "Based on our findings, disturbances in the normal cellular mechanisms for memory formation are likely to be among the earliest abnormalities in Alzheimer's disease. Specific therapies that correct the molecular defects identified in our study may be able to prevent or slow down subsequent neuronal death and cognitive deterioration."

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Carlos A. Saura, Se-Young Choi, Vassilios Beglopoulos, Seema Malkani, Dawei Zhang, B.S. Shankaranarayana Rao, Sumantra Chattarji, Raymond J. Kelleher III, Eric R. Kandel, Karen Duff, Alfredo Kirkwood, and Jie Shen: "Loss of Presenilin Function Causes Impairments of Memory and Synaptic Plasticity Followed by Age-Dependent Neurodegeneration"

Published online 1 April 2004 (DOI: 10.1016/S0896-627304001825). Appearing in print Volume 42, Number 1, 8 April 2004.


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