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Bi / CNS 150 Lecture 23 Friday November 22, 2014 Neurodegenerative diseases Bruce Cohen Kandel, Chapters 43, 44 (p. 1002 - 1012), 59 1 Neurodegenerative Diseases • Neurodegenerative diseases are characterized by an abnormal loss of neurons that begins in middle age or later and progressively increases until death • They are not considered part of normal aging • Neurodegenerative diseases typically result in the formation of atypical, subcellular protein assemblies such as amyloid plaques, neurofibrillary tangles, or lewy bodies • The three most common neurodegenerative diseases are Alzheimer disease (AD), Parkinson’s disease (PD), and Amyotrophic lateral sclerosis (ALS) 2 Alzheimer’s Disease Initially described by Alois Alzheimer in 1901 Disease progression I. Starts with memory loss and impaired cognitive abilities II. Middle stage, I. individuals may forget how to do simple tasks, like brushing their teeth or combing their hair II. They can no longer think clearly III. have problems speaking, understanding, reading, or writing. III. IV. Late stage, patients become anxious or aggressive, or wander away from home. Eventually, patients need total care. 3 Age is major risk factor for Alzheimer’s disease (AD) AD is the most common degenerative brain disease (est. 5 million USA, 25 million globally) The major risk factor is age • 65-74 75 80 >85 ~5% ~10% ~20% ~50% AD is not considered normal aging (even though 50% of people older than 85 show signs) • Most common form of AD (late-onset or sporadic AD) occurs late in life without obvious inheritance pattern. • Several risk factor genes may interact to cause the disease. • Most common genetic risk factor for late-onset AD is inheritance of a particular type of apolipoprotein E (apoE) called ApoE4 (prevalence ~ 16%), two copies of which produce a 3-4 fold dominant increase. • Familial AD, which is rarer, starts at age 30 - 60. 4 Cytological Hallmarks of Alzheimer’s Pathology: Amyloid Plaques and Neurofibrillary Tangles in Brain •Amyloid plaques contain large amounts of 42 amino acid peptide termed “bamyloid”, or Ab42 •b-amyloid itself causes initial pathophysiology that leads to dementia • Amyloid plaques probably contribute to the later stages of pathology •Neurofibrillary tangles are rich in cytoskeletal proteins, especially the microtubule-associated protein, “tau”. •In tangles, there are heavily phosphorylated proteins which may cause aggregation and precipitation of the cytoskeleton. Also, AD reduces brain volume, especially in entorhinal cortex and hippocampus 5 Presenilin 1 and APP mutations are associated with familial AD presenilin 1 is part of -secretase, a membrane-associated protease Hardy and Selkoe, 2002, Science 6 AD pathophysiology caused by proteolytic products from APP called Aβ40 and Aβ42 •β-APP is amyloid precursor protein. •APP proteins are 10 to 140 kDal. •APP expressed by most tissues, especially neurons •Found in axon terminals, dendrites, and glial cells. Overproduction of Ab40 and Ab42 results from altered ratio of proteolytic cleavages at sites termed a, b, and . Kandel et al.,Principles of Neural Science © McGraw-Hill Professional Publishing 7 Genetic risk factors for AD increase accumulation of Aβ peptides Chromosome Gene defect Phenotype 21 β-APP mutations ↑All Aβ peptides, or Aβ40 peptides A673T is an APP mutation that is neuroprotective for AD ↓ Aβ peptides, AD, cognitive decline 19 ApoE4 polymorphism (ε4 allele) ↑Density of Aβ plaques & vascular deposits 14 Presenilin 1 mutation ↑Production of Aβ42 peptides 1 Presenilin 2 mutation ↑Production of Aβ42 peptides 6 TREM2 ↑Density of Aβ plaques “Aβ (especially Aβ42) microaggregates—also termed “soluble Aβ oligomers” or “Aβ-derived diffusible ligands” (ADDLs)—constitute the neurotoxic species that causes AD” – Sheng, 2012 Abnormal states of tau mediate some effects of β-amyloid. This stage may be distal to the more toxic dimers and oligomers. 8 Soluble Aβ oligomers block induction of long-term potentiation Wild Type CM (Injected into ventricles 10 min before high frequency stimulation of the rat Schaffer collateral pathway). CM = “conditioned medium” from a cell line engineered to express Aβ CM + Aβ oligomers CM + Antibody against Aβ CM + nonspecific “control” antibody Walsh et al., Nature 2002 9 Parkinson’s disease James Parkinson, apothecary surgeon described "paralysis agitans” from observations of 6 individuals during his daily walks in London in An Essay on the Shaking Palsy (1817) Classic motor symptoms: tremor at rest 3-5 Hz, “pill-rolling” slow movements, particularly when initiating locomotion short, rapid steps Dramatization of the motor problems in a PD patient http://www.youtube.com/watch?feature=endscreen&v=j86omOwx0Hk&NR=1x 10 Selective loss of dopaminergic neurons in the human brain causes motor signs of PD Substantia Nigra: Dopaminergic neurons die in PD Rodent brain section, stained for tyrosine hydroxylase: coronal view 11 Flow chart of motor system hierarchy 1212 The Basal Ganglia: Major inputs “striatum” 13 13 Basal ganglia-thalamocortical circuit •Basic wiring of basal ganglia •Cortical neurons excite medium spiny neurons (MSNs) in Putamen (upper right) •MSNs receive modulatory input from dopaminergic neurons in Substania Nigra pars compacta (SNc) •MSNs are GABAergic and inhibit neurons in the Globus Pallidus internal (Gpi) and external segments (GPe) •Dopaminergic input to MSNs leads to inhibition of GPi neurons and disinhibits thalamic and pedunculopontine neurons •Disinhibition of these neurons allows voluntary motor movements •Loss of dopaminergic neurons in SNc impairs initiation of voluntary movement 14 Intracellular “Lewy bodies” in dopaminergic neurons are hallmark of PD pathology Lewy bodies can also occur in other diseases such as frontotemporal dementia 15 a-synuclein has an unknown function; it’s an “intrinsically disordered protein”. Mutant a-synuclein forms fibrils. The hallmark of PD pathology: Intracellular “Lewy bodies”, especially in dopamine neurons Improper mitochondrial fission / fusion may be an early event 16 PD treated with L-dopa HO H2 C NH3+ CO2- enzyme: decarboxylase HO levodopa, “L-dopa” zwitterion permeates into brain via a transporter HO H2 C C H2 NH3+ HO dopamine does not enter brain Used with carbidopa, which inhibits decarboxylase. Prevents hydrolysis in the blood and in the peripheral nervous system. D2 receptor agonist is often added. This seems to reduce dyskinesias 17 •Deep brain stimulation for Parkinson’s disease •Stimulting electrode placed in subthalamic nucleus (STn) •Tuned to frequencies that inactivate STn activity Nestler, Hyman, Malenka, Molecular Neuropharmacology, © McGraw-Hill Professional Publishing https://www.youtube.com/watch?v=a_4_DvquSYQ 18 Bruce Cohen’s office hours, 1:15-2 328 Kerckhoff 1. Alzheimer’s disease (AD) produces overall loss of neurons 2. AD causes formation of amyloid plaques 3. Accumulation of soluble Aβ oligomers appears to cause neuronal damage in AD 4. Parkinson’s disease (PD) creates problems with voluntary motor movements 5. Motor symptoms in PD due to loss of dopaminergic neurons in SNc 6. PD causes formation of Lewy bodies in neurons 19