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Protein conformational disorders Amyloid

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Title: Protein conformational disorders Amyloid


1
Protein conformational disordersAmyloid
Alice Skoumalová
2
  • Hypothetical protein folding pathway
  • (hierarchical)
  • local segments of secondary structure
  • tertiary structure (subdomains, domains)
  • stable conformation

3
Local minimum (alternative conformation)
Global minimum (native state)
  • the protein folding proceeds from a disordered
    state to progressively more ordered
    conformations corresponding to lower energy
    levels
  • there are more ways of folding (the same protein
    can aquire more conformations alternative
    conformations are represented by local energy
    minima)

Alternative conformations various function of
the protein disease-associated protein
4
a-helix
ß-sheet
Conformational change
  • the starting point is the natural protein folded
    in the native and active conformation
  • normal protein is rich in a-helix conformations
    (folded structure)
  • the end-point is the same protein adopting
    prevalent ß-sheets structure
  • it is disease-associated protein (misfolded
    structure)

Aggregation
Gain of toxic activity
Loss of biological function
5
  • The conformational change
  • a change in the secundary or tertiary structure
    of a normal protein without alteration of the
    primary structure
  • the biological function of a protein depends on
    its tridimensional structure
  • Protein conformatinal disorders (PCD)
  • diverse diseases arise from protein misfolding
  • the conformational change may promote the disease
    by either gain of a toxic activity or by the
    lack of biological function of the natively
    folded protein

6
  • Protein misfolding causes disease!
  • the hallmark event in PCD is a formation of
    ß-sheet conformations
  • the production of ß-sheets is usually stabilized
    by protein oligomerization and aggregation
  • the misfolded protein self-associates and becomes
    deposited in amyloid-like aggregates in diverse
    organs, inducing tissue damage and organ
    dysfunction

7
Three different hypotheses have been proposed to
describe the relationship between conformational
changes and aggregation
Polymerization hypothesis Aggregation induces the
protein conformational changes
Conformational hypothesis Protein misfolding is
independent of aggregation, which is a
non-necessary end point of conformational
changes (the factors inducing the protein
structural changes are e.g. mutations, oxidative
stress)
8
Conformation-oligomerization hypothesis Slight
conformational changes result in the formation of
an unstable intermediate which is stabilized by
intermolecular interactions with other molecules
forming small ß-sheet oligomers
9
Proteins that are not able to achieve the native
state
Recognition
Degradation (protein quality control
system) 1.Chaperones 2. Ubiquitin proteasome
system
10
Protein quality control in the cell
11
DNA
Ubiquitin
Ribosome
RNA
ATP
Chaperones
Native protein
Misfolded protein
Aggregate/fibrillar amyloid
Chaperones
Proteasome
Accumulation (Amyloidoses)
Degraded protein
Gain of toxicity (Alzheimer disease)
Loss of protein function (Cystic fibrosis)
12
  • Implication of protein misfolding
  • 1. Gain of toxicity
  • The harmfull effect of the misfolded protein may
    be due to deleterious gain of function as seen in
    many neurodegenerative disorders (Alzheimer
    disease, Parkinson disease, Hungtington disease),
    in which protein misfolding results in the
    formation of harmfull amyloid. Neurodegenerative
    diseases are characterized by the accumulation of
    misfolded proteins and formation of aggregates
  • 2. Loss of function
  • Other effect of the misfolded protein may be due
    to loss of function, as observed in cystic
    fibrosis. There is a mutation in the CFTR
    sequence
  • 3. Accumulation
  • Protein aggregates are sometimes converted to a
    fibrillar structure. Fibrils themselves are not
    toxic but insoluble. Their accumulation cause
    tissue damage (amyloidoses)

13
  • Chaperones
  • assist other proteins to achieve a functionally
    active 3D structure
  • prevent the formation of a misfolded or
    aggregated structure
  • Molecular chaperones recognise misfolded protein,
    bind to the hydrophobic surfaces and inhibit
    aggregation. Most of these molecules are heat
    shock proteins (formed during thermal
    damage)-protect against denaturation.
  • Pharmacological chaperones bind to specific
    conformations and stabilize them. They are
    effective in rescuing proteins from proteasomal
    degradation.

14
Molecular chaperones
Hsp 70 - prevent folding of nascent chain
Chaperonins reverse misfolded structures
15
  • Therapy
  • Considering that protein misfolding and
    aggregation are central in the pathogenesis of
    PCD, a therapy directed to the cause of the
    disease should aim to inhibit and reverse the
    conformational changes
  • Development of novel peptides which can
    destabilize the abnormal conformation might be
    useful to correct protein misfolding. Misfolded
    protein is rich in ß-sheet sructure, designed
    peptides prevent and reverse ß-sheet formation
    (ß-sheet breakers)
  • Molecular chaperones play an important role in
    protein folding,
  • chemical and pharmacological chaperones are
    experimentally studied

16
  • Amyloid
  • Amyloid is an aggregated protein sructure
    consisting of unbranched microscopic fibrils
    often found in dense tissue deposits and
    associated with a variety of human diseases
  • The term amyloid does not pertain to a specific
    protein molecule or sequence, but rather to a
    general folding motif that appears in various
    proteins
  • The amyloid structure exhibit a characteristic
    folding pattern, called a cross- ß structure
  • Amyloid is a pathogenic structure, formed by
    accident under conditions of molecular, cellular,
    or organismic stress, from proteins that evolved
    to fold and function in different structural
    states

17
Polypeptide Major disease states Transthyretin
Heart, kidney, peripheral neuropathy Serum
amyloid A Kidney, peripheral neuropathy Immunogl
obulin light chain Kidney, heart Immunoglobulin
heavy chain Spleen ß2-Microglobulin Carpal
tunnel syndrome, osteoarthropathies Islet
amyloid polypeptide Diabetic pancreatic islet
cells Fibrinogen a-chain Kidney Apolipoprotein
A1 Peripheral neuropathy, liver Atrial
natriuretic peptide Heart Amyloid ß-protein
(Aß) Brain (Alzheimers disease, cerebral
amyloid angiopathy) a-Synuclein Brain
(Parkinsons disease) Huntingtin polyglutamine
Brain (Huntingtons disease) sequence Prion
protein (PrP) Brain (Creutzfeldt-Jakob
disease, mad cow disease) Cystatin C,
Gelsolin Brain (cerebral amyloid
angiopathy) ABri Brain (familial British
dementia)
18
  • Molecular factors in amyloid formation
  • Protein misfolding is central to amyloid
    formation
  • Protein stability- the resistance of the folded
    conformation to misfolding- is an important
    factor in determining susceptibility to amyloid
    formation
  • Destabilizing factors
  • 1. Extreme environments in the body, such as
    acidic cell compartments
  • 2. Proteolytic removal of a portion of a protein
    by an endogenous protease
  • 3. Mutations that alter the primary structure
    (many of the amyloid diseases involve amino acid
    substitutions in an amyloid precursor protein)

19
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20
  • Amyloid fibril structure
  • Straight, unbranched, diameters in the range of
    80-160A
  • Composed of two to six protofilaments of diameter
    30-40A
  • Rich in a type of ß-sheet structure (the ß-sheets
    are perpendicular to the fibril axis and bind
    together by the hydrogen bonds)

ß2-microglobulin amyloid fibrils
21
  • Overview of amyloid diseases (amyloidosis)
  • Systemic amyloidosis
  • 1. Primary
  • The cause is unknown abnormal production of
    immunoglobulins insoluble protein fibers are
    deposited in tissues and organs, impairing their
    function The organs affected tongue, intestines,
    skeletal and smooth muscles, nerves, skin,
    ligaments, heart, liver, spleen, and kidneys
  • 2. Secondary
  • Caused by infection, inflammatory diseases, and
    sometimes cancer
  • 3.Familial
  • Mutations that make the proteins more prone to
    aggregation and amyloid deposition (e.g.
    transthyretin)
  • Organ-specific amyloidosis
  • Diabetes mellitus type 2 (amylin)
  • Alzheimers disease (Aß)
  • Parkinsons disease (a-synuclein)
  • Huntingtons disease (huntingtin)
  • Transmissible spongioform encephalopathies (prion
    protein)
  • Cardiac amyloidosis (PrP or transthyretin)

22
  • Toxicity of amyloid fibrils
  • 1. Amyloid can cause life-threatening disease by
    accumulating in such high mass that normal tissue
    structure and function are disrupted (systemic
    amyloidosis)
  • 2. The accumulated mass of amyloid is very low
    compared to the surrounding cell mass
    (neurodegenerative diseases)
  • 1. Collateral damage caused by immune responses
    to an amyloid deposits
  • 2. Membrane depolarization resulting from
    channels created by amyloid fibril assembly
    intermediates inserted into membranes
  • 3. Recruitment of other proteins into growing
    aggregates, which has the effect of denying the
    cell activity of the recruited proteins
  • 4. Disruption of the normal cellular apparatus
    for breakdown and elimination of misfolded
    proteins, such as the ubiquitin-proteasome system
    and the molecular chaperones

23
Questions
  • Describe the protein folding funnel
  • The hallmark event in PCD and consequences
  • The fate of a misfolded protein in the cell
  • The role of chaperons
  • Amyloid - formation, toxicity

24
Pictures used in the presentation Marks Basic
Medical Biochemistry, A Clinical Approach, third
edition, 2009 (M. Lieberman, A.D.
Marks) Principles of Biochemistry, Third Edition,
2008 (D.J. Voet, J.G. Voet, C.W. Pratt)
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