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Loss of Parkin in Mammals Takes Steam Out of Mitochondria
14
March 2004. A report in press in the Journal of Biological Chemistry,
published online February 24, adds to the growing body of evidence that
traces the etiology of Parkinson's disease to the mitochondria. Jie
Shen and colleagues at Brigham and Women's Hospital, Boston, reveal
that many mitochondrial proteins are downregulated in mice lacking the
protein parkin.
Parkin mutations, of course, have been linked to familial, early-onset Parkinson's disease since 1998 (see ARF related news story).
Being a ubiquitin ligase, parkin has been generally thought to protect
against this devastating disease by preparing other proteins for
destruction. Much research has, therefore, focused on the relationship
between parkin and proteins that end up in Lewy bodies. These are
intracellular inclusions that foul up dopaminergic neurons of the
substantia nigra, the part of the brain most affected by Parkinson's.
However, in fruit fly models of the disease made by ablating parkin,
dopaminergic neurons are hardly affected, while muscle mitochondria
seem particularly compromised (see ARF related news story).
More recently, Shen has shown that knocking out the gene in mice causes
some physiological changes to the substantia nigra, but without the
decimation of neurons that is observed in humans, and without altering
likely parkin substrates, such as α-synuclein and synphilin (see Goldberg et al., 2003). So in mice, what are the biochemical consequences of losing parkin?
To address this issue, joint first authors James Palacino and
Dijana Sagi adopted a comparative proteomics approach. They prepared
extracts from the substantia nigra of both parkin-negative and normal
mice, then separated the proteins by large, two-dimensional
electrophoresis. When they analyzed these chromatographs, they could
identify about 8,000 proteins, of which only 15 varied quantitatively
between the two samples. Fourteen of these were downregulated in the
parkin-deficient animals. To identify these proteins, the authors subjected them to mass
spectroscopy, and were surprised to find that nine of the 14 proteins
are mitochondrial. Five are involved in oxidative phosphorylation,
while four are involved in managing oxidative stress. The results
suggest that parkin plays a major role in maintaining mitochondrial
function. In support of this, the authors found that the
parkin-deficient mice gained weight more slowly, had decreased serum
antioxidant capacity, and increased protein and lipid peroxidation
compared to normal animals. The last finding, in particular, suggests
that parkin somehow protects against reactive oxygen species. As these
are, for the most part, produced in the mitochondria, parkin may
somehow prevent their production, possibly by maintaining flow through
the electron transport chain; the authors also found that mitochondrial
respiration is reduced in the mutant mice.
All told, these findings bolster the view that Parkinson's
disease is connected with mitochondrial fitness. MPTP, for example, has
been used for years to induce an experimental disease that models
Parkinson's, and this chemical attacks the mitochondria, as does
rotenone, a pesticide chemical that induces Parkinson's-like symptoms
(see ARF related news story).
And several groups have reported hints that polymorphisms in the DNA
that is often forgotten—mitochondrial DNA—can alter the risk of
Parkinson's disease (Van der Walt, 2001; Ross et al., 2003; Tanaka, 2002).—Tom Fagan.
Reference:
Palacino JJ, Sagi K, Goldberg MS, Krauss S, Motz C, Klose J, Shen J.
Mitochondrial dysfunction and oxidative damage in Parkin-deficient
mice. PNAS 2004 January 9;303:197-202. Abstract
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Comments on News and Primary Papers |
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Comment by: Mark Cookson
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Submitted 14 March 2004
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Posted 14 March 2004
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This
is a great paper. The parkin mice were surprisingly phenotype-free,
which seemed a nuisance, but may actually be helpful in this model, as
Shen and her colleagues were able to look at proteome differences in
the absence of changes in cell number. From my understanding, the
original rationale was to look for proteins that change in abundance as
a result of lack of E3 ligase activity. However, as the news summary
points out, they identified two major groups of proteins: mitochondrial
oxidative phosphorylation and oxidative stress response proteins.
The mitochondrial proteins were generally downregulated. This is
very exciting with reference to Leo Pallanck's group's paper showing a
mitochondrial phenotype in parkin knockout flies (although mitochondria
here are normal), and the reports of parkin suppressing mitochondrial
damage by Alexis Brice's lab. Also, the hint from Peter Heutink's
studies that DJ-1 is also mitochondrial in some circumstances may be
relevant. Peroxiredoxins are also interesting; these are proteins that
are often altered by oxidative stress; the other major one is DJ-1
(Mitsumoto et al., 2001). In many cases, the loss of one isoform
correlates with the appearance of a more acidic form, which would be
worth following up on.
What isn't clear yet is how Parkin causes these changes. These
proteins aren't known to be parkin substrates. In fact, there aren't
any known substrates that would induce a mitochondrial phenotype; these
would seem well worth looking for.
References:
Mitsumoto A, Nakagawa Y, Takeuchi A, Okawa K,
Iwamatsu A, Takanezawa Y. Oxidized forms of peroxiredoxins and DJ-1 on
two-dimensional gels increased in response to sublethal levels of
paraquat. Free Radic Res. 2001 Sep;35(3):301-10. Abstract
Greene JC, Whitworth AJ, Kuo I, Andrews LA, Feany MB, Pallanck
LJ. Mitochondrial pathology and apoptotic muscle degeneration in
Drosophila parkin mutants. Proc Natl Acad Sci U S A. 2003 Apr
1;100(7):4078-83. Abstract
Darios F, Corti O, Lücking CB, Hampe C, Muriel MP, Abbas N, Gu
WJ, Hirsch EC, Rooney T, Ruberg M, Brice A. Parkin prevents
mitochondrial swelling and cytochrome c release in
mitochondria-dependent cell death. Hum Mol Genet. 2003 Mar
1;12(5):517-26. Abstract
View all comments by Mark Cookson
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Comment by: Junchao Tong
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Submitted 16 March 2004
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Posted 17 March 2004
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The
paper did not discuss the current limitation of proteome technology.
Isn't it a coincidence that the proteins identified in this paper are
mostly from mitochondria while most of the identifiable proteins on a
2D PAGE are also metabolism enzymes (see Lubec et al., 2003)?
References:
Lubec et al., Progress in Neurobiology, 2003, 69:193
View all comments by Junchao Tong
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Primary Papers: Mitochondrial Dysfunction and Oxidative Damage in parkin-deficient Mice.
Comment by: Kazuhiro Honda, Quan Liu, Paula Moreira, George Perry (ARF Advisor) (Disclosure), Mark A. Smith (Disclosure), Xiongwei Zhu
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Submitted 30 April 2004
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Posted 30 April 2004
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Parkin and Mitochondria: Are They Allies in the War Against Parkinson’s Disease?
This exciting study by Palacino and colleagues shows an alliance
between two of the best-studied features of Parkinson's disease,
namely, mitochondrial dysfunction and parkin. Since parkin was
demonstrated to have E3 ubiquitin ligase activity (Shimura et al.,
2000), many researchers hypothesized that an unknown substance that
should be degraded by ubiquitination causes degeneration of nigral
neurons. Supporting this hypothesis, several substrates of parkin, such
as synphilin-1, CDC-rel1 and PAEL receptor, have been linked to nigral
function (Zhang et al., 2000; Chung et al., 2001; see Imai et la., 2001
in ARF related news story).
On the other hand, some groups, including the authors, reported that
parkin null mice did not show apparent nigral dopaminergic neuron
degeneration, but instead induced dysfunction to these neurons
(Goldberg et al., 2003). Interestingly, neuronal death in Parkinson’s
disease that results from ectopic expression of human α-synuclein is
mitigated by coexpression of human parkin (see Petrucelli et al., 2002
in ARF related news story).
Therefore, the net effect of loss of parkin on nigral neurodegeneration
remains unclear. In this study, the authors demonstrated that deletion
of parkin results in reduction of the proteins involved in
mitochondrial function and oxidative balance. Recently, Darios and
colleagues (2003) observed that PC32 cells overexpressing parkin are
more resistant to cell death induced by ceramide. They observed that
parkin acted by delaying mitochondrial swelling and subsequent
cytochrome c release and caspase-3 activation observed in ceramide cell
death. This exciting finding supports the idea that oxidative stress is
an early pathophysiological process involved in the neurodegeneration
of nigral dopaminergic neurons. This study shows the reduction of several components of
NADH-ubiquinone oxidoreductase (complex I) or cytochrome oxidase
(complex IV). Since these components are coded by mtDNA, which seems to
be more susceptible to oxidative stress induced by mitochondria than
those coded by nuclear DNA, this observation may not simply reflect
leakage of reactive oxygen species from impaired electron transport
chain. The normal number and morphology of mitochondrion are also
consistent with this view. However, the study presented by Darios et
al. (2003) showed an enrichment of parkin in the mitochondrial fraction
and its association with the outer mitochondrial membrane, suggesting
that parkin may promote the degradation of substrates localized in
mitochondria. We hope that further study can solve this riddle.
References:
Chung KK, Zhang Y, Lim KL, Tanaka Y, Huang H,
Gao J, Ross CA, Dawson VL, Dawson TM. Parkin ubiquitinates the
alpha-synuclein-interacting protein, synphilin-1: implications for
Lewy-body formation in Parkinson disease. Nat Med. 2001
Oct;7(10):1144-50. Abstract
Darios F, Corti O, Lucking CB, Hampe C, Muriel MP, Abbas N, Gu
WJ, Hirsch EC, Rooney T, Ruberg M, Brice A. Parkin prevents
mitochondrial swelling and cytochrome c release in
mitochondria-dependent cell death. Hum Mol Genet. 2003 Mar
1;12(5):517-26. Abstract
Goldberg MS, Fleming SM, Palacino JJ, Cepeda C, Lam HA,
Bhatnagar A, Meloni EG, Wu N, Ackerson LC, Klapstein GJ, Gajendiran M,
Roth BL, Chesselet MF, Maidment NT, Levine MS, Shen J. Parkin-deficient
mice exhibit nigrostriatal deficits but not loss of dopaminergic
neurons. J Biol Chem. 2003 Oct 31;278(44):43628-35. Epub 2003 Aug 20. Abstract
Imai Y, Soda M, Inoue H, Hattori N, Mizuno Y, Takahashi R. An
unfolded putative transmembrane polypeptide, which can lead to
endoplasmic reticulum stress, is a substrate of Parkin. Cell. 2001 Jun
29;105(7):891-902. Abstract
Palacino JJ, Sagi D, Goldberg MS, Krauss S, Motz C, Wacker M,
Klose J, Shen J. Mitochondrial Dysfunction and Oxidative Damage in
parkin-deficient Mice. J Biol Chem. 2004 Apr 30;279(18):18614-18622.
Epub 2004 Feb 24. Abstract
Petrucelli L, O'Farrell C, Lockhart PJ, Baptista M, Kehoe K,
Vink L, Choi P, Wolozin B, Farrer M, Hardy J, Cookson MR. Parkin
protects against the toxicity associated with mutant alpha-synuclein:
proteasome dysfunction selectively affects catecholaminergic neurons.
Neuron. 2002 Dec 19;36(6):1007-19. Abstract
Shimura H, Hattori N, Kubo S, Mizuno Y, Asakawa S, Minoshima S,
Shimizu N, Iwai K, Chiba T, Tanaka K, Suzuki T. Familial Parkinson
disease gene product, parkin, is a ubiquitin-protein ligase. Nat Genet.
2000 Jul;25(3):302-5. Abstract
Zhang Y, Gao J, Chung KK, Huang H, Dawson VL, Dawson TM. Parkin
functions as an E2-dependent ubiquitin- protein ligase and promotes the
degradation of the synaptic vesicle-associated protein, CDCrel-1. Proc
Natl Acad Sci U S A. 2000 Nov 21;97(24):13354-9. Abstract
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