Cofilin rods and aggregates signify events initiated early in the pathological cascade. Further definition of the mechanisms leading to their formation in the human brain will provide insights into the cellular causes of AD.
Excitotoxicity may contribute to neuronal and synaptic loss in Alzheimer's disease (AD). Aberrant levels of gephyrin, a post-synaptic receptor-stabilizing protein, could affect the inhibitory modulation of excitatory impulses. We assayed gephyrin protein in two brain areas susceptible to neuronal loss in AD, and in a spared area, in autopsy tissue from normal subjects (n = 15) and AD patients (n = 15). Quantification was by in-gel immunodetection against known concentrations of a recombinant truncated gephyrin standard. Gephyrin abundance was significantly reduced (P < 0.01) in AD. Area-wise analysis showed that gephyrin levels were reduced in both spared and susceptible regions, indicating a global phenomenon. When samples were categorized on an index of pathological severity, gephyrin levels decreased with increasing severity until a moderate index was reached, and then increased, suggesting that higher gephyrin levels might compensate for excitotoxic damage in late stages of the disease. AD males showed a more pronounced reduction in gephyrin levels than AD females cf same-sex controls. A major splice variant of gephyrin was detected in all cases and in all three brain areas. This is the first study of gephyrin expression in AD.
We have developed a novel functional nucleic acid aptamer to amyloid-β peptide 1-40 (Aβ1-40) and investigated its potential to detect Aβ peptide fragments in neuropathologically confirmed Alzheimer brain hippocampus tissues samples. Our results demonstrate that the aptamer candidate RNV95 could detect tetrameric/pentameric low-molecular-weight Aβ aggregates in autopsy hippocampal tissue from two neuropathologically confirmed Alzheimer disease cases. Although these are preliminary observations, detailed investigations are under way. This is the first demonstration of aptamer-Aβ binding in Alzheimer brain tissues.
Regionally specific neuronal loss is a distinguishing feature of Alzheimer disease (AD). Excitotoxicity is a mechanism commonly invoked to explain this. We review the accumulating evidence for such a hypothesis, particularly the altered expression and pharmacology of glutamate receptors and transporters in pathologically susceptible regions of the AD brain. Loss of neurons would be expected to lead to the retrograde degeneration of their afferents, which should be reflected in a loss of presynaptic markers such as synaptophysin. We discuss the possibility that neurons may be destroyed locally, but that glutamatergic presynaptic terminals may remain, or even re-proliferate. The reduced glutamate uptake site density in AD brain may signify a loss of the transporters on otherwise intact terminals, rather than the loss of glutamatergic afferents. Neuronal death may follow if cells are exposed to excessive amounts of glutamate; the loss of transporters from functioning, but defective, glutamate terminals would mean they could continue to release glutamate to exacerbate excitotoxicity. We discuss experimental methods to quantitate synapses, which are crucial for deciding between the various possibilities.
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