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2005
Department of Animal
Physiology-II, Faculty of Biological Sciences,
Complutense University, Madrid, 28040, Spain.
Previous studies in mammalian
models indicate that the rate of mitochondrial
reactive oxygen species ROS production and
the ensuing modification of mitochondrial
DNA (mtDNA) link oxidative stress to aging
rate. However, there is scarce information
concerning this in relation to caloric restriction
(CR) in the brain, an organ of maximum relevance
for ageing. Furthermore, it has never been
studied if CR started late in life can improve
those oxidative stress-related parameters.
In this investigation, rats were subjected
during 1 year to 40% CR starting at 24 months
of age. This protocol of CR significantly
decreased the rate of mitochondrial H(2)O(2)
production (by 24%) and oxidative damage
to mtDNA (by 23%) in the brain below the
level of both old and young ad libitum-fed
animals. In agreement with the progressive
character of aging, the rate of H(2)O(2)
production of brain mitochondria stayed
constant with age. Oxidative damage to nuclear
DNA increased with age and this increase
was fully reversed by CR to the level of
the young controls. The decrease in ROS
production induced by CR was localized at
Complex I and occurred without changes in
oxygen consumption. Instead, the efficiency
of brain mitochondria to avoid electron
leak to oxygen at Complex I was increased
by CR. The mechanism involved in that increase
in efficiency was related to the degree
of electronic reduction of the Complex I
generator. The results agree with the idea
that CR decreases aging rate in part by
lowering the rate of free radical generation
of mitochondria in the brain.
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Section of Biochemistry
and Molecular Biology, Department of Chemistry,
Faculty of Medicine, University of Catania,
Catania, Viale Andrea Doria 6, 95100 Catania,
Italy.
There is significant evidence
that the pathogenesis of several neurodegenerative
diseases, including Parkinson's disease,
Alzheimer's disease, Friedreich's ataxia
(FRDA), multiple sclerosis and amyotrophic
lateral sclerosis, may involve the generation
of reactive oxygen species (ROS) and/or
reactive nitrogen species (RNS) associated
with mitochondrial dysfunction. The mitochondrial
genome may play an essential role in the
pathogenesis of these diseases, and evidence
for mitochondria being a site of damage
in neurodegenerative disorders is based
in part on observed decreases in the respiratory
chain complex activities in Parkinson's,
Alzheimer's, and Huntington's disease. Such
defects in respiratory complex activities,
possibly associated with oxidant/antioxidant
imbalance, are thought to underlie defects
in energy metabolism and induce cellular
degeneration. The precise sequence of events
in FRDA pathogenesis is uncertain. The impaired
intramitochondrial metabolism with increased
free iron levels and a defective mitochondrial
respiratory chain, associated with increased
free radical generation and oxidative damage,
may be considered possible mechanisms that
compromise cell viability. Recent evidence
suggests that frataxin might detoxify ROS
via activation of glutathione peroxidase
and elevation of thiols, and in addition,
that decreased expression of frataxin protein
is associated with FRDA. Many approaches
have been undertaken to understand FRDA,
but the heterogeneity of the etiologic factors
makes it difficult to define the clinically
most important factor determining the onset
and progression of the disease. However,
increasing evidence indicates that factors
such as oxidative stress and disturbed protein
metabolism and their interaction in a vicious
cycle are central to FRDA pathogenesis.
Brains of FRDA patients undergo many changes,
such as disruption of protein synthesis
and degradation, classically associated
with the heat shock response, which is one
form of stress response. Heat shock proteins
are proteins serving as molecular chaperones
involved in the protection of cells from
various forms of stress. In the central
nervous system, heat shock protein (HSP)
synthesis is induced not only after hyperthermia,
but also following alterations in the intracellular
redox environment. The major neurodegenerative
diseases, Alzheimer's disease (AD), Parkinson's
disease (PD), amyotrophic lateral sclerosis
(ALS), multiple sclerosis (MS), Huntington's
disease (HD) and FRDA are all associated
with the presence of abnormal proteins.
Among the various HSPs, HSP32, also known
as heme oxygenase I (HO-1), has received
considerable attention, as it has been recently
demonstrated that HO-1 induction, by generating
the vasoactive molecule carbon monoxide
and the potent antioxidant bilirubin, could
represent a protective system potentially
active against brain oxidative injury. Given
the broad cytoprotective properties of the
heat shock response there is now strong
interest in discovering and developing pharmacological
agents capable of inducing the heat shock
response. This may open up new perspectives
in medicine, as molecules inducing this
defense mechanism appear to be possible
candidates for novel cytoprotective strategies.
In particular, manipulation of endogenous
cellular defense mechanisms, such as the
heat shock response, through nutritional
antioxidants, pharmacological compounds
or gene transduction, may represent an innovative
approach to therapeutic intervention in
diseases causing tissue damage, such as
neurodegeneration.
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Division of Neuroscience,
Ottawa Health Research Institute, 725 Parkdale
Avenue, Ottawa, Ontario, Canada K1Y 4K9.
Axonal degeneration is
a prominent pathological feature in multiple
sclerosis observed over a century ago. The
gradual loss of axons is thought to underlie
irreversible clinical deficits in this disease.
The precise mechanisms of axonopathy are
poorly understood, but likely involve excess
accumulation of Ca ions. In healthy fibers,
ATP-dependent pumps support homeostasis
of ionic gradients. When energy supply is
limited, either due to inadequate delivery
(e.g., ischemia, mitochondrial dysfunction)
and/or excessive utilization (e.g., conduction
along demyelinated axons), ion gradients
break down, unleashing a variety of aberrant
cascades, ultimately leading to Ca overload.
During Na pump dysfunction, Na can enter
axons through non-inactivating Na channels,
promoting axonal Na overload and depolarization
by allowing K egress. This will gate voltage-sensitive
Ca channels and stimulate reverse Na-Ca
exchange, leading to further Ca entry. Energy
failure will also promote Ca release from
intracellular stores. Neurotransmitters
such as glutamate can be released by reverse
operation of Na-dependent transporters,
in turn activating a variety of ionotropic
and metabotropic receptors, further exacerbating
overload of cellular Ca. Together, this
Ca overload will inappropriately stimulate
a variety of Ca-dependent enzyme systems
(e.g., calpains, phospholipases), leading
to structural and functional axonal injury.
Pharmacological interruption at key points
in these interrelated injury cascades (e.g.,
at voltage-gated Na channels or AMPA receptors)
may confer significant neuroprotection to
compromised central axons and supporting
glia. Such agents may represent attractive
adjuncts to currently available immunomodulatory
therapies.
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Department of Sport Biology,
Faculty of Sport Sciences, Porto, Portugal.
Severe high-altitude hypoxia
exposure is considered a triggering stimulus
for redox disturbances at distinct levels
of cellular organization. The effect of
an in-vivo acute and severe hypobaric hypoxic
insult (48h at a pressure equivalent to
8500m) on oxidative damage and respiratory
function was analyzed in skeletal muscle
mitochondria isolated from vitamin E supplemented
(60mg.kg(-1) i.p., 3 times/wk for 3 wks)
and non-supplemented mice. Forty male mice
were randomly divided into 4 groups: control+placebo
(C+P), hypoxia+placebo (H+P), control+vitamin
E (C+V) and hypoxia+vitamin E (H+V). Significant
increases in mitochondrial HSP60 expression,
protein carbonyls groups (CGs) levels and
decrease in aconitase activity and sulfhydryl
groups (SH) content were found in the H+P
group when compared with the C+P group.
Mitochondrial respiration was significantly
impaired in animals from the H+P group as
demonstrated by decreased state 3, respiratory
control ratio (RCR) and ADP/O, and by increased
state 4 with both complex I and II-linked
substrates. Using malate+pyruvate (MP) as
substrates, hypoxia decreased the respiratory
rate in the presence of CCCP (carbonyl cyanide
m-chlorophenylhydrazone) and also stimulated
oligomycin-inhibited respiration. However,
vitamin E treatment attenuated the effect
of hypoxia on the mitochondrial levels of
HSP60 and markers of oxidative stress. Vitamin
E was also able to prevent most mitochondrial
alterations induced by hypobaric hypoxia.
In conclusion, hypobaric hypoxia increases
mitochondrial oxidative stress while decreasing
mitochondrial capacity for oxidative phosphorylation.
Vitamin E was an effective preventive agent
which further supports the oxidative character
of mitochondrial dysfunction induced by
hypoxia.
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Departamento de Bioquimica,
Instituto de Quimica, Universidade de Sao
Paulo, Sao Paulo, SP, Brazil.
Ischemia followed by reperfusion
results in impairment of cellular and mitochondrial
functionality due to opening of mitochondrial
permeability transition pores. On the other
hand, activation of mitochondrial ATP-sensitive
K(+) channels (mitoK(ATP)) protects the
heart against ischemic damage. This study
examined the effects of mitoK(ATP) and mitochondrial
permeability transition on isolated rat
heart mitochondria and cardiac cells submitted
to simulated ischemia and reperfusion (cyanide/aglycemia).
Both mitoK(ATP) opening, using diazoxide,
and the prevention of mitochondrial permeability
transition, using cyclosporin A, protected
against cellular damage, without additive
effects. MitoK(ATP) opening in isolated
rat heart mitochondria slightly decreased
Ca(2+) uptake and prevented mitochondrial
reactive oxygen species production, most
notably in the presence of added Ca(2+).
In ischemic cells, diazoxide decreased ROS
generation during cyanide/aglycemia while
cyclosporin A prevented oxidative stress
only during simulated reperfusion. Collectively,
these studies indicate that opening mitoK(ATP)
prevents cellular death under conditions
of ischemia/reperfusion by decreasing mitochondrial
reactive oxygen species release secondary
to Ca(2+) uptake, inhibiting mitochondrial
permeability transition.
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2001
Department of Experimental
Pathology, University of Bologna, Italy.
A new perspective is emerging
indicating that mitochondria play a critical
role in aging not only because they are
the major source and the most proximal target
of reactive oxygen species, but also because
they regulate stress response and apoptosis.
Recent literature indicates that, in response
to stress, a variety of molecules translocate
to and localise in mitochondria. These molecules
are likely to interact with each other,
in order to mediate mitochondria/nucleus
cross-talk and to regulate apoptosis. We
surmise that an integration of signals in
multimolecular complexes occurs at mitochondrial
level. These phenomena can be of critical
importance for human aging and longevity.
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2000
Department of
Gene Therapy, Gifu International Institute
of Biotechnology, Yagi Memorial Park, Mitake,
Gifu, 505-0116, Japan.Institute of
Applied Biochemistry, Yagi Memorial Park,
Mitake, Gifu, 505-0116, Japan.
Mitochondria are not only
the major site of ATP production in cells
but also an important source of reactive
oxygen species (ROS) under certain pathological
conditions. Because mitochondrial DNA (mtDNA)
in the mitochondrial matrix is exposed to
ROS that leak from the respiratory chain,
this extranuclear genome is prone to mutations.
Therefore, the mitochondrial genome is a
rich source of single nucleotide polymorphisms
(SNPs) and the functional significance of
SNPs in the mitochondrial genome is comparable
to that of SNPs in the entire nuclear genome.
To demonstrate the contribution of mitochondrial
SNPs to the susceptibility to adult-onset
diseases, we analyzed the mtDNA from Japanese
centenarians and identified a longevity-associated
mitochondrial genotype, Mt5178A. Because
this genotype was demonstrated to suppress
the occurrence of mtDNA mutations in the
oocytes, it also would seem to decelerate
the accumulation of mtDNA mutations in the
somatic cells with increasing age. This
genotype is likely to confer resistance
to adult-onset diseases by suppressing obesity
and atherosclerosis.
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1998
Department of Biochemistry,
School of Life Science, National Yang-Ming
University, Taipei, Taiwan, Republic of
China.
Mitochondrial respiration
and oxidative phosphorylation are gradually
uncoupled, and the activities of the respiratory
enzymes are concomitantly decreased in various
human tissues upon aging. An immediate consequence
of such gradual impairment of the respiratory
function is the increase in the production
of the reactive oxygen species (ROS) and
free radicals in the mitochondria through
the increased electron leak of the electron
transport chain. Moreover, the intracellular
levels of antioxidants and free radical
scavenging enzymes are gradually altered.
These two compounding factors lead to an
age-dependent increase in the fraction of
the ROS and free radical that may escape
the defense mechanism and cause oxidative
damage to various biomolecules in tissue
cells. A growing body of evidence has established
that the levels of ROS and oxidative damage
to lipids, proteins, and nucleic acids are
significantly increased with age in animal
and human tissues. The mitochondrial DNA
(mtDNA), although not protected by histones
or DNA-binding proteins, is susceptible
to oxidative damage by the ever-increasing
levels of ROS and free radicals in the mitochondrial
matrix. In the past few years, oxidative
modification (formation of 8-hydroxy-2'-deoxyguanosine)
and large-scale deletion and point mutation
of mtDNA have been found to increase exponentially
with age in various human tissues. The respiratory
enzymes containing the mutant mtDNA-encoded
defective protein subunits inevitably exhibit
impaired respiratory function and thereby
increase electron leak and ROS production,
which in turn elevates the oxidative stress
and oxidative damage of the mitochondria.
This vicious cycle operates in different
tissue cells at different rates and thereby
leads to the differential accumulation of
mutation and oxidative damage to mtDNA in
human aging. This may also play some role
in the pathogenesis of degenerative diseases
and the age-dependent progression of the
clinical course of mitochondrial diseases.
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