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Current
Pharmaceutical Design
ISSN: 1381-6128
Current Pharmaceutical Design
Volume 14, Number 30, 2008
Contents
Anti-Amyloidogenic/Protein-Misfolding
Therapies in Amyloidosis and Other Protein-Misfolding Disorders
Executive Editor: Masahito Yamada
Editorial: Pp.
3203-3204
Structure, Formation and Propagation of Amyloid Fibrils
Pp. 3205-3218
Y. Goto, H. Yagi, K. Yamaguchi, E. Chatani
and T. Ban
[Abstract] [Purchase
Article]
Pathogenesis of and Therapeutic Strategies
to Ameliorate the Transthyretin Amyloidoses Pp.
3219-3230
Y. Sekijima, J.W. Kelly and S.-i.
Ikeda
[Abstract] [Purchase
Article]
Amyloid β-Protein
Assembly as a Therapeutic Target of Alzheimer’s Disease
Pp. 3231-3246
G. Yamin, K. Ono, M. Inayathullah and
D.B. Teplow
[Abstract]
[Purchase
Article]
α-Synuclein
Assembly as a Therapeutic Target of Parkinson’s Disease
and Related Disorders Pp. 3247-3266
K. Ono, M. Hirohata and M. Yamada
[Abstract] [Purchase
Article]
Conformational Changes and Aggregation
of Expanded Polyglutamine Proteins as Therapeutic Targets
of the Polyglutamine Diseases: Exposed β-Sheet
Hypothesis Pp. 3267-3279
Y. Nagai and H.A. Popiel
[Abstract] [Purchase
Article]
Non-Steroidal Anti-Inflammatory Drugs
as Anti-Amyloidogenic Compounds Pp. 3280-3294
M. Hirohata, K. Ono and M. Yamada
[Abstract] [Purchase
Article]
Abstracts
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Editorial: Anti-Amyloidogenic/Protein-Misfolding Therapies
in Amyloidosis and Other Protein-Misfolding Disorders
Amyloidosis is a pathological condition where proteins
with diverse chemical composition are extracellularly deposited
as fibrils in the brain, heart, kidney, liver, pancreas, nerves,
and other tissues or organs resulting in their serious dysfunctions.
Misfolding or conformational changes of normally soluble proteins
lead to pathological deposition of fibrillar proteins with
a cross-β-pleated
configuration. In addition to amyloidosis characterized by
extracellular fibril deposition, protein-misfolding or conformational
disorders include diseases characterized by intracellular
deposition of fibrillar structures (inclusion bodies) such
as Lewy body diseases [Parkinson’s disease (PD) and
dementia with Lewy bodies (DLB)] and polyglutamine diseases
of the brain.
Amyloidosis is classified to (1) systemic amyloidosis that
involves various organs in the body, and (2) localized amyloidosis
that affects a specific organ. According to the amyloidogenic
protein, systemic amyloidosis is classified to several types
including immunoglobulin (AL), AA, transthyretin (TTR) [familial
amyloidotic polyneuropathy (FAP) and senile systemic amyloidosis
(SSA)], and β2-microglobulin
(β2-m)
amyloidoses (dialysis-related amyloidosis). An example of
localized amyloidosis is brain amyloidosis including amyloid
β-protein
(Aβ)
[Alzheimer’s disease (AD) and cerebral amyloid angiopathy
(CAA)] and prion protein amyloidoses (Creutzfeldt-Jakob disease
and related disorders). A pathologic process to amyloid deposition
includes: (1) production of amyloid precursor proteins, (2)
processing of the precursor proteins to amyloidogenic proteins
(monomers), and (3) protein misfolding (conformational change)
and aggregation, finally resulting in deposition of the fibrillar
proteins. The protein misfolding and aggregation is an essential
process, shared by different types of amyloidoses and other
protein-misfolding disorders. In this process, oligomeric
forms or intermediate states have been reported to be more
toxic than mature fibrils in Alzheimer’s disease or
other protein-misfolding disorders.
Previously, a disease-modifying therapy for amyloidosis had
been largely limited to the suppression of production of amyloid
precursor proteins; for example, familial TTR amyloidosis
caused by mutations of the TTR gene has been treated by transplantation
of the liver, TTR-producing organ. Recently, however, anti-amyloidogenic
or anit-protein misfolding therapies that target the process
of protein misfolding and aggregation have been under development,
and clinical trials with these therapies have been started
in some diseases.
In this issue, the experts in this research field discuss
molecular basis and therapeutic potentials of anti-amyloidogenic/protein-misfolding
therapies in these disorders. In the first article, Dr. Goto
and his colleagues [1] address recent advances in the structural
study of structure, formation, and propagation of amyloid
fibrils. On the basis of various approaches including solid-state
nuclear magnetic resonance (NMR), hydrogen/deuterium exchange
of amide protons, and total internal reflection fluorescence
microscopy, convincing models of amyloid structures, their
formation, and propagation have emerged. In the second article,
Dr. Sekijima and his colleagues [2] discuss the pathogenesis
of TTR amyloidosis (FAP/SSA), and suggest new strategies for
therapeutic interventions for replacement of liver transplantation
that is currently the only effective treatment for FAP. The
new strategies include stabilization of TTR tetramer (native
state) by small molecule binding in order to prevent its dissociation
to misfolded monomers. In the third article, Dr. Teplow and
his colleagues [3] discuss therapeutic strategies against
AD, the most common neurodegerative disease in the elderly.
They summarize recent efforts to develop disease-modifying
therapeutic agents targeting Aβ
assembly, including immunotherapy, nutraceuticals, and a variety
of candidate molecules, of which some have progressed to phase
III clinical trials, and the others are less mature, but have
therapeutic potential. In the fourth article, Dr. Ono and
our group [4] focus on aggregation of α-synuclein
(αS)
which is a major component of Lewy bodies, neuropathological
hallmarks of PD/DLB. Some compounds such as polyphenols are
found with anti-fibrillogenic, anti-oligomeric, and fibril-destabilizing
effects for αS,
indicating that they could be key molecules for development
of the preventives and therapeutics for PD/DLB and other αS-related
disorders (α-synucleinopathies).
In the fifth article, Drs. Nagai and Popiel [5] deal with
the polyglutamine (polyQ) diseases, including Huntington’s
disease and spinocerebellar ataxias, which are caused by an
abnormal expansion of the polyQ stretch in disease-causative
proteins. They discuss how expanded polyQ stretches undergo
a conformational change and assembly exerting toxicity, and
they provide approach to identify polyQ aggregate inhibitors
that could be effective for the polyQ diseases and other related
neurodegenerative diseases. In the sixth article, Dr. Hirohata
and our group [6] provide an overview of non-steroidal anti-inflammatory
drugs (NSAIDs) as anti-amyloidogenic compounds. Anti-amyloidognic
properties of some NSAIDs have emerged with new insight for
development of anti-AD drugs, and the anti-fibrillogenic and
fibril-destabilizing activities of NSAIDs for other proteins
such as αS
suggest they could be key molecules for development of drugs
for PD/DLB and other protein-misfolding disorders.
Rapid progress in development of disease-modifying therapies
based on anti-amyloidogenic or anti-protein-misfolding strategies
will allow emergence of preventive or curative treatments
for amyloidosis and other protein-misfolding disorders in
near future.
References
[1] Goto Y, Yagi H, Yamaguchi K, Chatani E, Ban T. Structure,
formation and propagation of amyloid fibrils. Curr Pharm Des
2008; 14(30): 3205-3218.
[2] Sekijima Y, Kelly JW, Ikeda S-I. Pathogenesis and therapeutic
strategies to ameliorate the transthyretin amyloidoses. Curr
Pharm Des 2008; 14(30): 3219-3230.
[3] Yamin G, Ono K, Inayathullah M, Teplow DB. Amyloid β-protein
assembly as a therapeutic target of Alzheimer’s disease.
Curr Pharm Des 2008; 14(30): 3231-3246.
[4] Ono K, Hirohata M, Yamada M. α-Synuclein
assembly as a therapeutic target of Parkinson’s disease
and related disorders. Curr Pharm Des 2008; 14(30): 3247-3266.
[5] Nagai Y, Popiel HA. Conformational changes and aggregation
of expanded polyglutamine proteins as therapeutic target of
the polyglutamine diseases: Exposed β-sheet
hypothesis. Curr Pharm Des 2008; 14(30): 3267-3279.
[6] Hirohata M, Ono K, Yamada M. Non-steroidal anti-inflammatory
drugs as anti-amyloidogenic compounds. Curr Pharm Des 2008;
14(30): 3280-3294.
Masahito Yamada MD, PhD
Professor and Chairman
Department of Neurology and Neurobiology of Aging
Kanazawa University Graduate School of Medical Science
13-1, Takara-machi
Kanazawa 920-8640
Japan
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Structure, Formation and Propagation of Amyloid Fibrils
Y. Goto, H. Yagi, K. Yamaguchi, E. Chatani
and T. Ban
Amyloid fibrils have been a critical subject in recent
studies of proteins since they are associated with the pathology
of more than 20 serious human diseases. Moreover, a variety
of proteins and peptides not related to diseases are able
to form amyloid fibrils or amyloid-like structures, implying
that amyloid formation is a generic property of polypeptides.
Although understanding the structure and formation of amyloid
fibrils is crucial, due to the extremely high molecular weight
and insolubility of amyloid fibrils, most of the conventional
techniques available for soluble proteins are not directly
applicable to these fibrils. However, structural studies using
solid-state NMR have shown that the basic motif of amyloid
fibrils is a β-strand-loop-β-strand
conformation often in a parallel β-sheet
assembly. From the hydrogen/deuterium exchange of amide protons,
amyloid fibrils have been shown to be stabilized by an extensive
network of hydrogen bonds substantiating β-sheets.
Our approach using total internal reflection fluorescence
microscopy combined with thioflavin T, an amyloid-specific
fluorescence dye, enabled monitoring fibril growth in real-time
at single fibril level. On the basis of these various approaches,
increasingly convincing models of amyloid structures, their
formation and propagation are emerging.
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Pathogenesis of and Therapeutic Strategies to Ameliorate the
Transthyretin Amyloidoses
Y. Sekijima, J.W. Kelly and S.-i.
Ikeda
Transthyretin (TTR) is a homotetrameric serum and cerebrospinal
fluid protein that transports both thyroxine (T4)
and the retinol-retinol binding protein complex (holoRBP).
Rate-limiting tetramer dissociation and rapid monomer misfolding
and misassembly of variant TTR results in familial amyloid
polyneuropathy (FAP), familial amyloid cardiomyopathy (FAC),
or familial central nervous system amyloidosis. Analogous
misfolding of wild-type TTR results in senile systemic amyloidosis
(SSA) characterized by sporadic amyloidosis in elderly populations.
With the availability of genetic and immunohistochemical diagnostic
tests, patients with TTR amyloidosis have been found in many
nations worldwide. Recent studies indicate that TTR amyloidosis
is not a rare endemic disease as previously thought. The only
effective treatment for the familial TTR amyloidoses is liver
transplantation; however, this strategy has a number of limitations,
including a shortage of donors, a requirement for surgery
for both the recipient and living donor, and the high cost.
Furthermore, a large number of patients are not good transplant
candidates. Recent studies focused on the TTR gene
and protein have provided insight into the pathogenesis of
TTR amyloidosis and suggested new strategies for therapeutic
intervention. TTR tetramer (native state) kinetic stabilization
by small molecule binding, immune therapy, and gene therapy
with small interfering RNAs, antisense oligonucleotides, and
single-stranded oligonucleotides are promising strategies
based on our understanding of the pathogenesis of TTR amyloidosis.
Among these, native state kinetic stabilization by diflunisal
and Fx-1006A, a novel therapeutic strategy against protein
misfolding diseases, are currently in Phase II/III clinical
trials.
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Amyloid β-Protein
Assembly as a Therapeutic Target of Alzheimer’s Disease
G. Yamin, K. Ono, M. Inayathullah and
D.B. Teplow
Alzheimer’s disease (AD), the most common neurodegenerative
disorder in the aged, is characterized by the cerebral deposition
of fibrils formed by the amyloid β-protein
(Aβ),
a 40-42 amino acid peptide. The folding of Aβ
into neurotoxic oligomeric, protofibrillar, and fibrillar
assemblies is hypothesized to be the key pathologic event
in AD. Aβ
is formed through cleavage of the Aβ
precursor protein by two endoproteinases, β-secretase
and α-secretase,
that cleave the Aβ
N-terminus and C-terminus, respectively. These facts support
the relevance of therapeutic strategies targeting Aβ
production, assembly, clearance, and neurotoxicity. Currently,
no disease-modifying therapeutic agents are available for
AD patients. Instead, existing therapeutics provide only modest
symptomatic benefits for a limited time. We summarize here
recent efforts to produce therapeutic drugs targeting Aβ
assembly. A number of approaches are being used in these efforts,
including immunological, nutraceutical, and more classical
medicinal chemical (peptidic inhibitors, carbohydrate-containing
compounds, polyamines, “drug-like” compounds,
chaperones, metal chelators, and osmolytes), and many of these
have progressed to phase III clinical trails. We also discuss
briefly a number of less mature, but intriguing, strategies
that have therapeutic potential. Although initial trials of
some disease-modifying agents have failed, we argue that substantial
cause for optimism exists.
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α-Synuclein Assembly as a Therapeutic Target of
Parkinson’s Disease and Related Disorders
K. Ono, M. Hirohata and M. Yamada
Lewy bodies (LBs) and Lewy neurites (LNs) in the brain
constitute the main histopathological features of Parkinson’s
disease (PD) and dementia with Lewy bodies (DLB), and are
comprised of amyloid-like fibrils composed of a small protein
(~14 kDa) named alpha-synuclein (αS).
As the aggregation of αS
in the brain has been implicated as a critical step in the
development of the diseases, the current search for disease-modifying
drugs is focused on modification of the process of αS
deposition in the brain. In this article, the recent developments
on the molecules that inhibit the formation of α-synuclein
fibrils (fαS)
as well as the oligomerization of αS
are reviewed. Recently, various compounds such as curcumin,
nicotine and wine-related polyphenols have been reported to
inhibit the formation of fαS,
and to destabilize preformed fαS
at pH 7.5 at 37°C
in vitro. Although the mechanisms by which these compounds
inhibit fαS
formation from fαS,
and destabilize preformed fαS
are still unclear, they could be key molecules for the development
of preventives and therapeutics for PD and other α-synucleinopathies.
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Conformational Changes and Aggregation of Expanded Polyglutamine
Proteins as Therapeutic Targets of the Polyglutamine Diseases:
Exposed β-Sheet
Hypothesis
Y. Nagai and H.A. Popiel
The polyglutamine (polyQ) diseases, including Huntington’s
disease and spinocerebellar ataxias, are classified as the
protein misfolding neurodegenerative diseases like Alzheimer’s
and Parkinson’s diseases, and they are caused by an
abnormal expansion of the polyQ stretch in disease-causative
proteins. Expanded polyQ stretches have been shown to undergo
a conformational transition to a β-sheet-dominant
structure, leading to assembly of the host proteins into insoluble
β-sheet-rich
amyloid fibrillar aggregates and their subsequent accumulation
as inclusion bodies in affected neurons, eventually resulting
in neurodegeneration. Based on cytotoxicity of the soluble
β-sheet
monomer of the expanded polyQ protein, we propose the “Exposed
β-sheet
hypothesis”, in which both the toxic β-sheet
conformational transition and misas-sembly into amyloid fibrils
of the disease-causative proteins contribute to the pathogenesis
of the polyQ diseases, and possibly the other protein misfolding
neurodegenerative diseases. Among the various therapeutic
targets, the toxic conformational changes and aggregation
of the expanded polyQ proteins are most ideal since they are
the earliest events in the pathogenic cascade, and therapeutic
approaches using molecular chaperones, intrabodies, peptides,
and small chemical compounds have been developed to date.
Furthermore, high-throughput screening approaches to identify
polyQ aggregate inhibitors are in progress. We hope that protein
aggregate inhibitors which are widely effective not only for
the polyQ diseases, but also for many neurodegenerative diseases
will be discovered in the near future.
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Non-Steroidal Anti-Inflammatory Drugs as Anti-Amyloidogenic
Compounds
M. Hirohata, K. Ono and M. Yamada
Amyloidosis is a clinical disorder caused by deposition
of proteins that abnormally self-assemble into insoluble fibrils
and impair organ function. More than 20 unrelated precursor
proteins lose their native structure and misfold, leading
to the formation of amyloid fibrils. The latter share cross-β
core structure in vivo and in vitro and
gain abnormal functions. Local amyloid deposition occurs in
the central nervous system in Alzheimer’s disease (AD)
and cerebral amyloid angiopathy. AD is the most common form
of neurodegenerative disorder, with dementia in the elderly
as well as dementia with Lewy bodies (DLB). Extracellular
deposition of amyloid β-peptide
(Aβ)
has been implicated as a critical step in the pathogenesis
of AD. Involvement of neuroinflammation and microglial activation
has been emphasized in the AD brain. Recent epidemiological
studies have shown that long-term therapeutic use of non-steroidal
anti-inflammatory drugs (NSAIDs) reduces the risk of developing
AD and delayed the onset of AD. We review epidemiological
studies of anti-AD effects of NSAIDs, experimental studies
of anti-amyloidogenic as well as anti-inflammatory effects
of NSAIDs, and recent clinical trials for AD with NSAIDs.
We refer to the anti-fibrillogenic and fibril-destabilizing
activities of NSAIDs for other proteins that can aggregate
and form amyloid-like fibrils, including α-synuclein
in DLB. The anti-amyloidogenic properties of some NSAIDs provide
new insights for future therapeutic and preventative opportunities
for AD and other amyloidoses, and protein-misfolding disorders.
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