Transcript Slide 1
Alzheimer's
Introduction
Alzheimer’s disease (AD) is a neurodegenerative disease associated
with brain shrinkage and the loss of neurons, particularly
cholinergic neurons. This mainly occurs in the hippocampus and
basal forebrain (as seen in figure 1). There are two features of AD
which are characteristic in sufferers; the formation of extracellular
amyloid plaques comprising of the β- amyloid protein (Aβ) and the
formation of intraneuronal neurofibrillary tangles consisting of the
Tau protein in an abnormal phosphorylated form, which causes it
to dissociate from microtubules and be deposited as intracellular
paired helical filaments (as seen in figure 2). Both of these
characteristics arise from the misfolding of native proteins in the
brain and can result in neuronal death.
Genetics
Pathology
Gene
Protein
Location
Type of AD
APP
Beta-amyloid precursor
protein
Chromosome 21
Familial
PS1
Presenilin 1
Chromosome 14
Familial
PS2
Presenilin 2
Chromosome 1
Familial
APOE4
Apolioprotein
Chromosome 19
Sporadic
Large quantity of protein aggregation
Hydrophobic residues exposed at
surface of protein increases
tendency that the protein will
become bound to the membrane
Build up of beta amyloid in the
neurons
Familial Alzheimer’s (FAD), also referred as Early-Onset Alzheimer’s is an
autosomal dominant condition.
Tau protein becomes heavily
phosphorylated and causes the
formation of helical filaments
Mutations in beta-amyloid precursor protein
The beta amyloid peptide (A40) is obtained from the proteolytic
processing of the beta-amyloid precursor protein. Different versions can
be obtained from alternatively spliced mRNA. These mutations lead to an
amyloidogenic form of beta amyloid peptide (A42/43), which is longer in
length. The most severe mutations cause large a decrease in A40, and a
large increase in A42. A40 doesn’t bind to more than 3 other A40
proteins, whereas A42 is able to bind to 11 other A42 proteins, these
form beta-sheets, which lead to the large fibrils that form the plaques.
Figure 1
Figure 1
Presenilin mutations
These mutations were responsible for most genetically-linked FAD. More
mutations identified in PS1 (approx. 107 point mutations vs 8 in PS2).
Mutations lead to a protein that cant undergo proteolysis. This leads to
increased production of A42. Not fully understood why, one theory is
that the mutations alter the gamma-secretase activity so more
amyloidogenic form of the A peptide (A42/43) is produced.
Sporadic Alzheimer’s (SAD) refers to Alzheimer’s cases where the disease
has not been present in close family members. SAD tends to be late-onset
(after 65) and has a higher prevalence than FAD. SAD occurs as a result of
several genetic mutations, ageing and environmental factors.
Figure 2
Only a single gene has evidently been associated with SAD- the ε4 allele of
the apolipoprotein E gene (APOE4) located on chromosome 19. APOE4 is a
lipoprotein; it is thought that mutations in this gene increase the risk of AD
by interfering with β-amyloid protein (Aβ) clearance. However the
presence of the ε4 allele does not always increase the risk of SAD. First
degree relatives of someone with SAD may inherit the mutant APOE4 gene
which will result in an increased risk of developing SAD themselves.
Proteasome mechanism, that should
degrade inactive proteins, fails
Beta amyloid plaques and
neurofibrillary tangles are formed
Transport of action potentials along
the axon is impaired
Reduced release of neurotransmitter
The cognitive ability of an
Alzheimer’s sufferer is decreased
Loss of cholinergic neurons
It was discovered in 1976 that the loss of cholinergic neurons in the basal
forebrain nuclei is a main characteristic in AD patients. The activity of
choline acetyltransferase (the enzyme responsible for the formation of the
neurotransmitter acetylcholine) is dramatically reduced in the cortex and
hippocampus. Nicotinic receptors have also been found in reduced
numbers in AD. Cholinesterase inhibitors are widely used to treat AD.
References :
http://phys.org/news165687229.html
Encyclopedia of molecular cell biology and molecular medicine
Flesh and Bones of Medical Cell Biology, Norman. Robert. I, Pages 29 & 89
Rang and Dale's Pharmacology, Rang, H.P, Page 476