| Current
Molecular Medicine
ISSN: 1566-5240
Current Molecular Medicine
Volume 8, Number 3, May 2008
Contents
Apoptosis, Necrosis and Autophagy: From
Mechanisms to Biomedical Applications (Part-II)
Guest Editor: Claudio Hetz
Apoptosis in the Nervous System
The Stress Rheostat: An Interplay Between
the Unfolded Protein Response (UPR) and Autophagy in Neurodegeneration
Pp. 157-172
Soledad Matus, Fernanda Lisbona, Mauricio Torres,
Cristian León, Peter Thielen and Claudio Hetz
[Abstract]
Programmed Cell Death Mechanisms in Neurological
Diseas. Pp. 173-186
Dale E. Bredesen
[Abstract]
Cell Death by Necrosis, a Regulated Way to Go
Pp. 187-206
Mauricio Henriquez, Ricardo Armisén, Andrés
Stutzin and Andrew F.G. Quest
[Abstract]
Molecular Mechanisms and Pathophysiology of Necrotic
Cell Death Pp. 207-220
Nele Vanlangenakker, Tom Vanden Berghe, Dmitri V. Krysko,
Nele Festjens and Peter Vandenabeele
[Abstract]
General Articles
Molecular Genetics and Biomarkers of Polyglutamine
Diseases Pp. 221-234
Masahisa Katsuno, Haruhiko Banno, Keisuke Suzuki,
Yu Takeuchi, Motoshi Kawashima, Fumiaki Tanaka, Hiroaki Adachi
and Gen Sobue
[Abstract]
Cutaneous Melanoma: Fishing with Chips Pp.
235-243
Sandeep Nambiar, Alireza Mirmohammadsadegh and
Ulrich R. Hengge
[Abstract]
Abstracts
[Back to top]
The Stress Rheostat: An Interplay Between the Unfolded Protein
Response (UPR) and Autophagy in Neurodegeneration
Soledad Matus, Fernanda Lisbona, Mauricio Torres,
Cristian León, Peter Thielen and Claudio Hetz
The unfolded protein response (UPR) is a conserved adaptive
reaction that increases cell survival under conditions of
endoplasmic reticulum (ER) stress. The UPR controls diverse
processes such as protein folding, secretion, ER biogenesis,
protein quality control and macroautophagy. Occurrence of
chronic ER stress has been extensively described in neurodegenerative
conditions linked to protein misfolding and aggregation, including
Amyotrophic lateral sclerosis, Prion-related disorders, and
conditions such as Parkinson’s, Huntington’s,
and Alzheimer’s disease. Strong correlations are observed
between disease progression, accumulation of protein aggregates,
and induction of the UPR in animal and in vitro models
of neurodegeneration. In addition, the first reports are available
describing the engagement of ER stress responses in brain
postmortem samples from human patients. Despite such findings,
the role of the UPR in the central nervous system has not
been addressed directly and its contribution to neurodegeneration
remains speculative. Recently, however, pharmacological manipulation
of ER stress and autophagy – a stress pathway modulated
by the UPR – using chemical chaperones and autophagy
activators has shown therapeutic benefits by attenuating protein
misfolding in models of neurodegenerative disease. The most
recent evidence addressing the role of the UPR and ER stress
in neurodegenerative disorders is reviewed here, along with
therapeutic strategies to alleviate ER stress in a disease
context.
[Back to top]
Programmed Cell Death Mechanisms in Neurological
Diseas
Dale E. Bredesen
Programmed cell death (pcd) is a form of cell death in
which the cell plays an active role in its own demise. Pcd
plays a critical role in the development of the nervous system,
as well as in its response to insult. Both anti-pcd and pro-pcd
modulators play prominent roles in development and disease,
including neurodegeneration, cancer, and ischemic vascular
disease, among others. Over 100,000 published studies on one
form of programmed cell death—apoptosis—have appeared,
but recent studies from multiple laboratories suggest the
existence of non-apoptotic forms of programmed cell death,
such as autophagic programmed cell death. In addition, there
appear to be programmatic cell deaths that do not fit the
criteria for either apoptosis or autop-hagic cell death, arguing
that additional programs may also be available to cells. Constructing
a mechanistic taxonomy of all forms of pcd—based on
inhibitors, activators, and identified biochemical pathways
involved in each form of pcd—should offer new insight
into cell deaths associated with various disease states, and
ultimately offer new therapeutic approaches.
[Back to top]
Cell Death by Necrosis, a Regulated Way to Go
Mauricio Henriquez, Ricardo Armisén, Andrés
Stutzin and Andrew F.G. Quest
Apoptosis is a programmed form of cell death with well-defined
morphological traits that are often associated with activation
of caspases. More recently evidence has become available demonstrating
that upon caspase inhibition alternative programs of cell
death are executed, including ones with features characteristic
of necrosis. These findings have changed our view of necrosis
as a passive and essentially accidental form of cell death
to that of an active, regulated and controllable process.
Also necrosis has now been observed in parallel with, rather
than as an alternative pathway to, apoptosis. Thus, cell death
responses are extremely flexible despite being programmed.
In this review, some of the hallmarks of different programmed
cell death modes have been highlighted before focusing the
discussion on necrosis. Obligatory events associated with
this form of cell death include uncompensated cell swelling
and related changes at the plasma membrane. In this context,
representatives of the transient receptor channel family and
their regulation are discussed. Also mechanisms that lead
to execution of the necrotic cell death program are highlighted.
Emphasis is laid on summarizing our understanding of events
that permit switching between cell death modes and how they
connect to necrosis. Finally, potential implications for the
treatment of some disease states are mentioned.
[Back to top]
Molecular Mechanisms and Pathophysiology of Necrotic
Cell Death
Nele Vanlangenakker, Tom Vanden Berghe, Dmitri V. Krysko,
Nele Festjens and Peter Vandenabeele
Necrotic cell death has long been considered an accidental
and uncontrolled mode of cell death. But recently it has become
clear that necrosis is a molecularly regulated event that
is associated with pathologies such as ischemia-reperfusion
(IR) injury, neurodegeneration and pathogen infection. The
serine/threonine kinase receptorinteracting protein 1 (RIP1)
plays a crucial role during the initiation of necrosis induced
by ligand-receptor interactions. On the other hand, ATP depletion
is an initiating factor in ischemia-induced necrotic cell
death. Common players in necrotic cell death irrespective
of the stimulus are calcium and reactive oxygen species (ROS).
During necrosis, elevated cytosolic calcium levels typically
lead to mitochondrial calcium overload, bioenergetics effects,
and activation of proteases and phospholipases. ROS initiates
damage to lipids, proteins and DNA and consequently results
in mitochondrial dysfunction, ion balance deregulation and
loss of membrane integrity. Membrane destabilization during
necrosis is also mediated by other factors, such as acid-sphingomyelinase
(ASM), phospholipase A2 (PLA2)
and calpains. Furthermore, necrotic cells release immunomodulatory
factors that lead to recognition and engulfment by phagocytes
and the subsequent immunological response. The knowledge of
the molecular mechanisms involved in necrosis has contributed
to our understanding of necrosis-associated pathologies. In
this review we will focus on the intracellular and intercellular
signaling events in necrosis induced by different stimuli,
such as oxidative stress, cytokines and pathogenassociated
molecular patterns (PAMPs), which can be linked to several
pathologies such as stroke, cardiac failure, neurodegenerative
diseases, and infections.
[Back to top]
Molecular Genetics and Biomarkers of Polyglutamine
Diseases
Masahisa Katsuno, Haruhiko Banno, Keisuke Suzuki,
Yu Takeuchi, Motoshi Kawashima, Fumiaki Tanaka, Hiroaki Adachi
and Gen Sobue
Polyglutamine diseases are hereditary neurodegenerative
disorders caused by an abnormal expansion of a trinucleotide
CAG repeat, which encodes a polyglutamine tract. To date,
nine polyglutamine diseases are known: Huntington’s
disease (HD), spinal and bulbar muscular atrophy (SBMA), dentatorubralpallidoluysian
atrophy (DRPLA) and six forms of spinocerebellar ataxia (SCA).
The diseases are inherited in an autosomal dominant fashion
except for SBMA, which shows an X-linked pattern of inheritance.
Although the causative gene varies with each disorder, polyglutamine
diseases share salient genetic features as well as molecular
pathogenesis. CAG repeat size correlates well with the age
of onset in each disease, shows both somatic and germline
instability, and has a strong tendency to further expand in
successive generations. Aggregation of the mutant protein
followed by the disruption of cellular functions, such as
transcription and axonal transport, has been implicated in
the etiology of neurodegeneration in polyglutamine diseases.
Although animal studies have provided promising therapeutic
strategies for polyglutamine diseases, it remains difficult
to translate these disease-modifying therapies to the clinic.
To optimize “proof of concept”, the process for
testing candidate therapies in humans, it is of importance
to identify biomarkers which can be used as surrogate endpoints
in clinical trials for polyglutamine diseases.
[Back to top]
Cutaneous Melanoma: Fishing with Chips
Sandeep Nambiar, Alireza Mirmohammadsadegh and
Ulrich R. Hengge
DNA microarray technology is a versatile platform
that allows rapid genetic analysis to take place on a genome-wide
scale and has revolutionized the way cancers are studied.
This platform has enabled researchers to characterize mechanisms
central to tumorigenesis and understand important molecular
events in the multi-step tumor progression model of cutaneous
melanoma and other cancers. In melanoma, multiple global gene
expression profiling studies using various DNA microarray
platforms and various experimental designs have been performed.
Each study has been able to capture and characterize either
the involvement of a novel pathway or a novel cause-effect-relationship.
The use of microarrays to define subclasses, to identify differentially
regulated genes within a mutational context to analyze epigenetically
regulated genes has resulted in an unprecedented understanding
of the biology of cutaneous melanoma that may lead to more
accurate diagnosis, more comprehensive prognosis, prediction
and more effective therapeutic interventions. Related DNA
microarray platforms like array-comparative genomic hybridization
(CGH) have also been instrumental to identify many non-random
chromosomal alterations; however, studies identifying validated
targets as a result of CGH are limited. Thus, there exists
significant opportunity to discover novel melanoma genes and
translate such discoveries into meaningful clinical endpoints.
In this review, we focus on various DNA microarray-based studies
performed in cutaneous melanoma and summarize our current
understanding of the genetics and biology of melanoma progression
derived from accumulating genomic information.
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