Aging: Dial M for Mitochondria
Abstract
A major goal of aging research is to identify interventions that prolong lifespan in distantly related organisms. In recent years, genetic studies in both nematodes and rodents have reported that moderate inactivation of genes important for mitochondrial electron transport chain (ETC) function can promote longevity. We performed an RNAi screen to probe the role of ETC components in modulating lifespan in the fruit flyDrosophila melanogaster. In this Research Perspective, we discuss our findings and how they may relate to similar studies in worms and mice.
Aging is characterized by a general decline in
physiological function that leads to morbidity and eventually, mortality. In recent years, significant progress has been made
in our understanding of the nature of these changes at the molecular level.
Due to the descriptive nature of these studies however,it has proven difficult to infer the relative
importance of the many processes that contribute to aging. Alterations in mitochondrial energy metabolism may be
particularly important because it is central to metabolism a vital process that
affects every aspect of cellular function. Moreover, genetic studies in a
number of model organisms have reported that inactivation of genes important
for mitochondrial function can have profound effects on lifespan.
In this Perspective, we discuss our recent findings in
the fruit fly Drosophila and how they relate to studies in other model
organisms, including mammals.
Age-related changes in mitochondrial function
Defects in mitochondrial electron transport chain
(ETC function and their effects on aging and age-related
disease have been widely reported [1,2]. Aged mammalian tissues show a decreased capacity to
produce ATP and the impairment of mitochondrial function has
been attributed to decreased rates of electron transfer by the
selectively diminished activities of complexes I and IV [3]. In addition
to decreased electron transfer and oxygen uptake, dysfunctional mitochondria in
aged rodents are characterized by increased oxidation products of
phospholipids, proteins andDNA, decreased membrane potential, and increased size
and fragility [4]. These features
of the aging process may be conserved across the animal kingdom. For example,
in Drosophila aging is also associated with changes in mitochondrial
structure [5,6] and a decline
in mitochondrial function [7]. As in
mammals, complex IV activity appears to be particularly vulnerable to both
aging [7] and oxidative
stress [6] in flies.
These observations have lead to the concept
of the "vicious cycle" in which an initial ROS-induced impairment of
mitochondria leads to increased oxidant production that, in turn, leads to
further mitochondrial damage [8].
Another possible explanation behind the age-related
decline in ETC function is the decline in expression of nuclear-encoded
components of the ETC. In one study, the
authors compared microarray data between two organisms (Caenorhabditis elegans and Drosophila)
as they aged in an effort to obtain a consensus aging transcriptsome. In both
species, there was a significant decrease in a large set of genes involved in
ATP synthesis and mitochondrial respiration [9]. Similar studies have identified age-related declines
in the expression of genes involved in ETC function in both humans and mice [10,11]. At present,
it is not known if these changes in gene expression are a cause, consequence or
correlate of the aging process.
Inactivation of genes important for ETC function
Caenorhabditis elegans
The link between mitochondrial energy metabolism and
longevity has been most extensively studied in the nematode C. elegans.
Numerous studies have demonstrated that direct disruption of the mitochondrial
electron transport chain (ETC) can produce large effects on lifespan. Although
short-lived mutants are often considered less informative than long-lived mutants
as they may result from novel pathologies unrelated to normal aging, the mev-1
mutant may be a notable exception. This short-lived mutant carries a mutation
in subunit C of mitochondrial complex II [12] and displays
elevated ROS production [13] which has been
proposed to be an important determinant of lifespan [8].
One of the first demonstrations that impaired ETC
function could increase lifespan was the isolation and characterization of a
long-lived mutant with a mutation in the iron sulfur protein (isp-1) of
mitochondrial complex III [14]. The
long-lived clk-1 mutant lacks an enzyme required in the biosynthesis of
ubiquinone, also known as coenzyme Q, an important electron acceptor for both
complex I- and II-dependent respiration [15]. These
results have been greatly expanded by a number of large-scale RNA-interference
(RNAi) screens that have demonstrated that reducing the level of various
components of respiratory chain complexes I, III, IV, or V results in
longer-lived worms [16-20]. In addition,
feeding worms a diet of respiratory deficient bacteria is also sufficient to
extend lifespan [21,22].
When interpreting these findings, it may
prove important to consider certain aspects of nematode ecology and physiology [23,24]. Worms make
their living in the soil and, if given a choice, prefer hypoxic conditions [25], under which
they can survive for remarkably long periods [26]. Physiologically, this may be enabled by an anaerobic
energy-generating pathway, not found in mammals, involving reverse electron transfer
via fumarate reductase and malate dismutation [27].
It may prove telling that the phenotypic consequences of elevated
mitochondrial oxidative stress differ in worms and other animals. Deletion of
the mitochondrial superoxide dismutase 2 (sod2) results in very severe shortening of lifespan in both flies [28] and mice [29]. In contrast, sod-2
deficiency in C. elegans has been reported to increase longevity in one
study [30] and have
negligible impact on longevity in another study [31]. Therefore,
it is possible that the physiological and phenotypic consequences of ETC
dysfunction may be different in worms compared to those in other animals.
With this in mind, we thought it important to examine the impact of moderate
inactivation of ETC genes in a different
model organism.
Drosophila melanogaster
The isolation and
characterization of a Drosophila mutant with a defect in the iron-sulfur
subunit (sdhB) of complex II was the first study to directly
investigate the effects of decreased ETC function on fly longevity [32].
Interestingly, the biochemical and phenotypic consequences of complex II
deficiency in flies are very similar to complex II (mev-1) deficiency in
worms. Specifically, our biochemical data indicate that SDHB is critical in
preventing electron leakage from complex II, so that mutant animals suffer from
increased oxidative stress and, as a result, are highly sensitive to oxygen and
die rapidly [32]. The fact
that inactivation of complex II had similar phenotypic effects in flies and
worms led us to question the consequences of moderate inactivation of other ETC
genes in the fly.
By happy coincidence the generation of a genome-wide
library of Drosophila RNAi transgenes [33] was reported
shortly before one of us (D.W.W) moved to UCLA to start his independent
research group. This technical advance allowed us to systematically inactivate
a large fraction of nuclear encoded ETC genes in living flies and study their
impact on longevity [34]. Not
surprisingly, we observed that many of the RNAi lines produced larval lethality
or shortened adult longevity. However, just like in the worm, we observed that
RNAi-inactivation of certain ETC genes resulted in enhanced longevity [34]. A major
conclusion of our study is that despite more than 600 million years of separate
evolution, partial inactivation of certain ETC genes can promote longevity in
both fies and worms. Furthermore, we observed that neuronal-specific RNAi mediated knock-down
of certain ETC genes was sufficient to extend lifespan. The effects on
longevity of tissue-specific ETC gene inactivations have not yet been reported
in C. elegans.
Shortly after publication of the results of the RNAi
screen, we reported that genetic and pharmacological treatments that target
complex V affect lifespan in a nutrient-dependent manner [35]. In an
independent study, similar observations were reported for complexes I and IV [36]. Together
these findings strongly suggest that altered ETC activity plays a critical role
in dietary restriction-mediated longevity in the fly.
Mammals
In humans, mitochondrial defects have been implicated
in a wide range of life-shortening degenerative diseases [2,37]. However, despite considerable progress in elucidating the
underlying genetic defects, the molecular pathogenesis events linking the
mutated gene to the observed clinical phenotype are poorly understood. Unfortunately, relatively few rodent models of ETC
deficiency have been reported. The generation of a mouse lacking subunit D of
complex II (SDHD) was reported as the first rodent model lacking a protein of
the ETC [38]. Animals
without an intact copy of sdhD die at early embryonic stages, while
heterozygotes display complex II deficiency without alterations in body weight
or major physiological dysfunction. More recently, it was reported that
inactivation of the Ndufs4 gene, which encodes an 18 kDa subunit of complex I,
leads to an early-onset (5 weeks) encephalomyopathy [39].
There have also been a number of reports indicating
that certain genetic manipulations that impair ETC function can protect against
oxidative stress, neurodegeneration, obesity, and diabetes, and prolong
longevity in mice. For example, tissue-specific deletion of apoptosis inducing
factor (AIF) leads to reduced ETC function and was shown to protect mice
against both diabetes and obesity [40,41]. Reduced activity of MCLK1, a mitochondrial enzyme
necessary for ubiquinone biosynthesis, leads to a severe reduction of ETC
function and a substantial increase in lifespan with no trade-off in growth or
fertility[42,43]. Finally,
mice carrying a disruption in SURF1, a putative complex IV assembly factor,
display a complex IV biochemical defect, markedly prolonged longevity and complete
protection from kainic acid-induced neurotoxicity [44]. It should be
noted that these studies do not directly manipulate ETC gene activity.
However, they clearly demonstrate that not all perturbations of ETC function in
mammals are deleterious. A recent study that did directly manipulate an ETC
gene supports the idea that under
specific conditions, ETC inhibition can
reduce oxidative stress and neurodegeneration in mammals. Targeted deletion of
a complex IV subunit (COX10) in neurons was shown to decrease both oxidative stress and amyloid plaque
formation in a mouse model of Alzheimer's disease [45].
Electron transport chain activity and longevity: less
is more?
Taken together, the work in flies, mice and the large
number of long-lived ETC mutant worms clearly demonstrates that decreased
expression of certain ETC genes is an evolutionarily conserved mode of lifespan
extension. However, the underlying mechanisms remain poorly understood. Our
own work indicates that ETC gene manipulations that prolong lifespan are not
necessarily associated with obvious energetic or physiological trade-offs. We
identified five ETC gene hypomorphs associated with increased longevity. However, only
two of the ETC gene knock-downs conferred detectable decreases in the abundance
of fully assembled respiratory complexes. In addition, none of the five ETC
gene perturbations resulted in a decrease in ATP levels. An important next
step will be a careful and detailed analysis of different aspects of
respiratory chain function in long-lived flies with reduced expression of ETC
genes.
Summary/Conclusions
Increased lifespan conferred byRNAi
of mitochondrial respiratory components is not limited to nematodes but is also
true for flies [34]. In addition, there is a growing body of data in mice,
linking moderate respiratory chain dysfunction with enhanced longevity. Thus
this mode of lifespan extension has the potential to be generally applicable to
animals, as is the case for dietary restriction and altered insulin/IGF-1
signaling. There is, therefore, an urgent need for a better understanding of
this ‘Public' mechanism of aging.
A challenge
that we find particularly pressing is to reconcile our results with the large
number of studies that report an age-related decline in ETC gene expression and
activity. If ETC activity decreases as a function of age, then it appears
counterintuitive that RNAi knock-down
of ETC genes would promote
longevity. In contrast, we might speculate that strategies to increase
respiratory chain function may prove effective in retarding the aging process.
In yeast, manipulations that increase respiration are associated with increased
longevity [46,47]. Critically, experimental manipulations
that directly increase the activity of respiratory enzymes in metazoans have
been lacking. And so, the consequences of increased respiratory chain activity in animals remain largely unexplored. It
is an exciting time to be studying the role of ETC activity in modulating
animal aging.
Acknowledgments
D.W.W received support from the UCLA Older Americans
Independence Center, NIH/NIA Grant P30-AG028748, and the content does not
necessarily represent the official views of the National Institute on Aging or
the National Institutes of Health. D.W.W also received support from the Ellison
Medical Foundation, the American Federation for Aging Research and the UCLA
Center for gene environment in Parkinson's Disease. D.W.W is an Ellison Medical
Foundation New Scholar in Aging.
Conflicts of Interest
The authors of this manuscript have no conflict of interest to declare.
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