Abstract
The human syndrome of coenzyme Q (CoQ) deficiency is a heterogeneous mitochondrial disease characterized by a diminution of CoQ content in cells and tissues that affects all the electron transport processes CoQ is responsible for, like the electron transference in mitochondria for respiration and ATP production and the antioxidant capacity that it exerts in membranes and lipoproteins. Supplementation with external CoQ is the main attempt to address these pathologies, but quite variable results have been obtained ranging from little response to a dramatic recovery. Here, we present the importance of modeling human CoQ deficiencies in animal models to understand the genetics and the pathology of this disease, although the election of an organism is crucial and can sometimes be controversial. Bacteria and yeast harboring mutations that lead to CoQ deficiency are unable to grow if they have to respire but develop without any problems on media with fermentable carbon sources. The complete lack of CoQ in mammals causes embryonic lethality, whereas other mutations produce tissue-specific diseases as in humans. However, working with transgenic mammals is time and cost intensive, with no assurance of obtaining results. Caenorhabditis elegans and Drosophila melanogaster have been used for years as organisms to study embryonic development, biogenesis, degenerative pathologies, and aging because of the genetic facilities and the speed of working with these animal models. In this review, we summarize several attempts to model reliable human CoQ deficiencies in invertebrates, focusing on mutant phenotypes pretty similar to those observed in human patients.
Key Words: Caenorhabditis elegans, Coenzyme Q deficiency, Drosophila melanogaster
Overview of Coenzyme Q Function and Biosynthesis
Coenzyme Q (CoQ) is the only lipid-soluble redox compound that is synthesized by all aerobic organisms studied to date, and it is essential for ATP production by the mitochondrial oxidative phosphorylation system. The redox activity of the benzoquinone ring allows CoQ to both flow electrons from mitochondrial complexes I and II to complex III and transport protons across the inner membrane [Albert et al., 2008]. CoQ is also the electron acceptor of several dehydrogenases, including those in fatty acid β-oxidation and in pyrimidine nucleotide synthesis [Lopez-Lluch et al., 2010; Nowicka and Kruk, 2010]. Additionally, CoQ functions as a potent lipid soluble antioxidant in the plasma membrane and elsewhere [Lopez-Lluch et al., 2010].
CoQ biosynthesis depends on a highly conserved multi-enzyme complex [Bentinger et al., 2010] that involves at least 10 COQ genes, and mutations in any of these genes cause primary CoQ10 deficiencies in human beings [Rahman et al., 2001]. Figure 1 represents the biosynthetic pathway of CoQ in eukaryotes, and table 1 compares the genes of yeast, humans, and invertebrates.
Table 1.
S. cerevisiaea | C. elegansb | D. melanogasterc | Humansd |
---|---|---|---|
COQ1 (YBR003W) | coq-1 (C24A11.9) | qless (cg31005) | COQ1/PDSS1 (COQ1, subunit 1) |
cg10585 (pdss2) | PDSS2/DLP1 (COQ1, subunit 2) | ||
COQ2 (YNR041C) | coq-2 (F57B9.4) | coq2 (cg9613) | COQ2 |
COQ3 (YOL096C) | coq-3 (Y57G11C.11) | coq3 (cg9249) | COQ3 |
COQ4 (YDR204W) | coq-4 (T03F1.2) | coq4 (cg32172) | COQ4 |
COQ5 (YML110C) | coq-5 (ZK652.9) | coq5 (cg2453) | COQ5 |
COQ6 (YGR255C) | coq-6 (K07B1.2) | coq6 (cg7277) | COQ6 (two isoforms: A and B) |
COQ7/CAT5 (YOR125C) | clk-1 (ZC395.2) | coq7 (cg14437) | COQ7 |
COQ8 (YGL119W) | coq-8 (C35D10.4) | coq8 (cg32649) | COQ8/ADCK3/CABC1 |
COQ9 (YLR201C) | coq9 (cg30493) | COQ9 | |
COQ10 (YOL008W) | coq-10 (R144.13) | coq10 (cg9410) | COQ10A (homolog A) COQ10B (homolog B) |
The polyisoprene tail of CoQ is produced by the COQ1 protein in yeast or by a dimeric enzyme in humans composed by a catalytic subunit (PDSS1) and a regulatory one (PDSS2). COQ1 defines the length of the polyisoprene tail of CoQ and, because this gene differs between species, each organism presents a specific CoQ isoform, i.e. CoQ6 for the yeast Saccharomyces cerevisiae, CoQ8 for Escherichia coli, CoQ9 in Caenorhabditis elegans, and CoQ10 in humans. The subscript numbers indicate the quantity of isoprene units and therefore the length of the CoQ tail. The isoprenyl tail originates from the mevalonate pathway which takes place in the endoplasmic reticulum and is shared for cholesterol biosynthesis, t-RNA and protein synthesis, protein glycosylation, and both geranylation and farnesylation of proteins for subcellular localization [Rauthan and Pilon, 2011].
The precursor of the redox-active head of CoQ (pHB, para-hydroxybenzoate) derives of tyrosine and is linked to the polyisoprene tail by the transferase COQ2 inside mitochondria. After that, the polyisoprenylated ring is subjected to various modifications in this organelle, including a decarboxylation (unknown protein), 3 hydroxylations (one carried out by COQ6 and another by COQ7; the protein responsible for the third is unknown), 1 C-methylation (done by COQ5), and 2 O-methylations (both by COQ3).
No catalytic functions have been established for COQ4, COQ8, COQ9, and COQ10, although they are suggested to be regulatory components of the biosynthetic pathway: COQ8 is supposed to be a regulatory kinase and COQ10 a chaperon for complex stability with CoQ-binding properties. See GeneCard® from ‘The Human Gene Compendium’ at www.genecards.org for a full description of the genes.
Summarizing the Human Syndrome of CoQ10 Deficiency
Given the central role that CoQ plays in metabolism, it is not surprising that mutations involving its biosynthesis lead to severe phenotypes and disorders. Bacteria and yeast harboring mutations in any of the genes involved in the CoQ biosynthetic pathway are unable to grow on media with non-fermentable carbon sources [Tran and Clarke, 2007]. The complete lack of CoQ in mammals, i.e. knockout mutations in mice, cause embryonic lethality [Levavasseur et al., 2001; Takahashi et al., 2008], whereas other mutations produce tissue-specific diseases in animals [Peng et al., 2008] as well as in humans [Quinzii and Hirano, 2010; Rahman et al., 2012].
Primary CoQ10 deficiencies are described as heterogeneous mitochondrial diseases [Rahman et al., 2001] (OMIM 607426). Clinical presentations include encephalomyopathy with lipid storage myopathy and myoglobinuria [Sobreira et al., 1997], ataxia and cerebellar atrophy [Artuch et al., 2006], severe infantile encephalomyopathy with renal failure [Salviati et al., 2005], isolated myopathy [Horvath et al., 2006], and nephrotic syndrome [Heeringa et al., 2011]. Secondary CoQ10 deficiency has also been associated with diverse mitochondrial diseases [Quinzii et al., 2006; Gempel et al., 2007; Montero et al., 2008; Haas et al., 2009; Cotan et al., 2011; Miles MV et al., 2011]. In all of these conditions, CoQ10 supplementation partially improves symptoms [Montini et al., 2008; Pineda et al., 2010; Schon et al., 2010] and usually induces a return to normal growth and respiration in CoQ10-deficient fibroblasts [Lopez-Martin et al., 2007; Lopez et al., 2010; Cotan et al., 2011]. Thus, adaption of somatic cells to a pathogenic mutation may affect both onset and course of CoQ10 deficiency in each patient or animal model.
Supplementation with external CoQ10 is the main attempt to address these pathologies. However, quite variable results have been obtained, ranging from little response to a dramatic recovery [Quinzii and Hirano, 2010; Rahman et al., 2012]. Here, we present the importance of modeling human CoQ deficiencies in animal models to understand the genetics and the pathology of this disease.
CoQ Deficiency in the Worm C. elegans
C. elegans is a free-living transparent nematode (roundworm) which has been used extensively as a model organism for molecular and developmental biology [Albert et al., 2008] mainly due to the easy way to study the loss of function of a gene by silencing with RNAi, which can be done by simply feeding the worms with transgenic bacteria expressing RNA complementary to the gene of interest [Kamath et al., 2003].
Many genes take part in CoQ biosynthesis in C. elegans (table 1), although some of them have no catalytic activity. Interference with RNAi of these genes leads to CoQ deficiency in the nematode [Asencio et al., 2003]. In addition, inhibition of mitochondrial respiration or CoQ production causes increased expression of cell-protective genes and produces a rise of mitochondrial DNA content compared to wild-type nematodes which is related with slowing down of behavioral rates and lifespan extension [Cristina et al., 2009]. Besides its effects on biological rates and longevity, CoQ contributes to the robustness of specific developmental processes, like extracellular matrix degradation driving severe abnormalities in the hypodermis, abnormal gonads development and germ line mortality, and alteration of behavioral rates and the aging process. These and other phenotypes due to CoQ deficiency will be described below.
C. elegans clk-1 mutants lack the production of CoQ9 and accumulate the intermediate demethoxy-ubiquinone (DMQ9), the substrate of the COQ7 O-methyltransferase [Jonassen et al., 2001]. These worms display a pleiotropic phenotype, including slowed pharyngeal pumping and abnormalities in defecation, movement, embryogenesis, and larvae development [Wong et al., 1995]. Interestingly, adult clk-1 mutants reproduce for many generations, live longer than wild-type N2 worms, and show a reduction of fertility and slow behaviors [Wong et al., 2005], although they fail to develop and become sterile when fed a CoQ-less diet of E. coli [Jonassen et al., 2001]. These investigations suggest that either dietary CoQ8 from E. coli [Jonassen et al., 2001] or the intermediate DMQ9 [Levavasseur et al., 2001] could supply the CoQ9 role in mitochondria to drive respiration, giving the long-lived phenotype shown by clk-1 mutants.
However, it has been demonstrated that mitochondria from clk-1 mutants synthesize a small amount of CoQ9 [Arroyo et al., 2006] as does the equivalent mutant yeast when grown in long-term cultures [Padilla et al., 2004]. The small amount of CoQ6 synthesized by this mutant yeast is necessary for assembly and stability of the mitochondrial complex III to allow subsequent respiration [Santos-Ocaña et al., 2002]. Thus, either the small amount of CoQ9 endogenously synthesized by clk-1 mutants or the CoQ8 coming from diet would stabilize complex III, and the accumulated intermediate DMQ9 would support a sufficient level of respiration.
Clk-1 mutants show defects in the complexes I-III of CoQ-dependent mitochondrial activities, while activity from complex II-III remain unchanged [Kayser et al., 2004]. Recent studies indicate that DMQ9 present in clk-1 mutants could inhibit complex I but not complex II [Yang et al., 2011]. The kinetics of complex I shows a higher Km for CoQ than complex II [Lenaz, 1998]. As a result, the limiting amount of CoQ9 in clk-1 mutant affects complexes I-III activity more than II-III activity. On the other hand, the intermediate compound DMQ9 competes with CoQ9, for DMQ9 being less effective than CoQ9 in electron transfer. As a result, DMQ9 could be a functional inhibitor of electron transport in the respiratory chain at the level of complex I [Yang et al., 2011]. However, several studies have concluded that DMQ can neither substitute the CoQ function in mitochondrial respiration [Padilla et al., 2004] nor its redox activity in the plasma membrane [Arroyo et al., 2006]. Moreover, DMQ is unable to serve as an effective antioxidant [Padilla et al., 2004]. Thus, the subsequently reduction in the electron flow of the respiratory chain through inhibition of complex I could scavenge reactive oxygen-species production, being the reason of the life extension phenotype shown by clk-1 mutants.
Several attempts have been done to address the clk-1 phenotype by administrating exogenous CoQ, although the effects on behavioral rates, mitochondrial function, and lifespan are controversial. The administration of a water-soluble CoQ10 (Aqua Q10L10) restored the behavioral rates, such as the pharyngeal pumping and defecation, and reduced both mean and maximal lifespan to levels comparable to those of wild-type nematodes [Takahashi et al., 2012]. In contrast, clk-1 mutant nematodes, fed genetically engineered bacteria that produce CoQ10 instead of their own CoQ8, exhibit a decrease in mitochondrial oxidative damage and a greater extension of lifespan, although the mitochondrial respiration rates were not improved [Yang et al., 2009]. However, the mutant phenotype was not enhanced if clk-1 nematodes were fed with CoQ6, CoQ7, CoQ8, or even with CoQ9-repleted bacteria, indicating that CoQ10 is the CoQ isoform with higher antioxidant properties. A study that supports the antioxidant role of CoQ10 was done in wild-type animals, demonstrating that dietary supplement of CoQ10 extended the lifespan of worms by releasing oxidative stress [Ishii et al., 2004].
Other CoQ-deficient C. elegans described to date have a more severe phenotype and are much less responsive to dietary CoQ supplementation when compared to clk-1. First generation of coq-1 mutants are sterile and present both morphological defects and improper development of the organs [Gavilan et al., 2005]. Also, knockdown of coq-1 by feeding bacteria producing RNAi against this gene results in the progressive degeneration of GABA neurons and age-dependent loss of motor coordination [Earls et al., 2010]. This uncoordinated phenotype emerges during late larval development, progresses in adulthood, and proceeds with a selective cell death pathway activation where apoptotic and mitochondrial fission genes take part, which is a clear signal of initiation of a mitophagy process within these cells as in humans [Rodríguez-Hernández et al., 2009; Cotan et al., 2011]. However, neurons and body muscle cells that use other neurotransmitters, such as dopamine, acetylcholine, serotonin, or glutamate, were more resistant to CoQ depletion [Earls et al., 2010]. Similar phenotypes were described within the same work for knockdown of the genes coq-2 and coq-3.
C. elegans harboring partial deletions of the coq-3 gene show a more diverse phenotype: coq-3(qm188) mutants do not develop reproductive organs and subsequently become sterile [Hihi et al., 2002], whereas coq-3(ok506) mutants retain fertility for the first generation, although only a small fraction of the second generation survives into adulthood [Gomez et al., 2012].
An attempt to rescue the defective phenotype in these mutants was done by feeding worms with either OP50 wild-type bacteria (containing its own CoQ8 isoform) or NovaSOL® Q10 (a water-soluble commercial CoQ10 provided by AQUANOVA, Germany). One third of the coq-3(ok506) larvae developed if fed with OP50 bacteria, although no successful development was achieved in the coq-3(qm188) strain [Gomez et al., 2012]. Similarly to clk-1 mutants, coq-1, coq-2, or coq-3 mutant worms fed with a diet containing the CoQ-defective bacteria GD1 failed in larval development. However, if this diet was supplemented with NovaSOL® Q10, about 30% of the clk-1 larvae completed development, although no rescue was achieved for any coq-1, coq-2, or coq-3 mutants [Gomez et al., 2012].
Nevertheless, a full rescue of the coq-3 mutant phenotype was achieved by an extra-chromosomal array containing the own C. elegans coq-3 gene despite the phenotypic disparity shown by coq-3(qm188) and coq-3(ok506) strains [Gomez et al., 2012]. Both transgenic worms showed a dramatic rescue, illustrating the crucial role the endogenous synthesized CoQ9 isoform plays in fertility and development.
First-generation homozygous coq-8 mutants show developmental delay, decreased fertility, and both extracellular matrix degradation and severe abnormalities in the hypodermis, suggesting that it is detached from muscle cells [Asencio et al., 2009]. Most of the embryos produced are arrested between the second and eighth cell division after fertilization, and their second-generation progenies, which lack the maternal inherited CoQ9, become sterile because they do not properly develop gonads.
Coq-8 knockouts do not present differences in longevity in respect to the wild-type worm if fed a CoQ-rich diet with wild-type E. coli, although the lifespan is reduced to a half if they are fed the CoQ-deficient GD1 bacteria [Asencio et al., 2009]. However, no improvement of fertility was observed with a CoQ-rich diet, but embryo production was increased, and most of the embryos completed the development if uridine was added simultaneously to the plates containing CoQ-repleted E. coli, indicating that the pyrimidine nucleotide pathway necessary for DNA synthesis (and the subsequent embryo arrest after fertilization) cannot be restored by external CoQ [Asencio et al., 2009].
Finally, other mitochondrial disorders that alter the CoQ9 level have been described in C. elegans, even when the disease-causing mutation does not affect any of the genes directly involved in CoQ synthesis. An example is the mev-1 mutant which is defective in the mitochondrial complex II and presents a reduction of 25% in the content of CoQ9 [Vasta et al., 2011]. Other mutations disturbing the mitochondrial complexes I and III, like the gas-1 and isp-1 mutants, respectively, do not show significant reduction of CoQ9 compared to that of wild-type nematodes. However, all of them have altered rates of the reduced and oxidized forms of CoQ, ubiquinol and ubiquinone, respectively. As expected by deficiency in such mitochondrial respiratory complexes, both gas-1 (complex I defective) and mev-1 (complex II defective) mutants are unable to reduce CoQ9 in mitochondria and present a significant increase in the amount of ubiquinone, whereas the isp-1 (complex III defective) mutants are unable to oxidize CoQ9 and show higher levels of ubiquinol [Vasta et al., 2011]. So, the phenotype described by these mutants could be classified as a secondary CoQ9 deficiency in C. elegans.
CoQ Deficiency in the Fruit Fly Drosophila melanogaster
Drosophila melanogaster is a species of Diptera in the family Drosophilidae which is known generally as the common fruit fly or vinegar fly. It has been widely used for biological research in studies of genetics, development and organogenesis [Maung and Jenny, 2011], physiology [Teleman et al., 2012], microbial pathogenesis [Limmer et al., 2011], therapeutic drug discovery in pharmacology [Pandey and Nichols, 2011], degenerative diseases [Grice et al., 2011], cardiomyopathies [Qian and Bodmer, 2012], inflammatory diseases [Roeder et al., 2012], cancer [Miles WO et al., 2011; Zhang et al., 2011], aging [Sanz et al., 2010; Biteau et al., 2011; Katewa and Kapahi, 2011], and life history evolution [Carey, 2011].
Regarding mitochondria, Drosophila has been used to model several human diseases [Sánchez-Martínez et al., 2006, 2012; Oliveira et al., 2010], to study the genetic base of a mitochondrial disease [Kemppainen et al., 2009; Fernández-Ayala et al., 2010], or even for developing mitochondrial gene therapy [Fernandez-Ayala et al., 2009].
However, the fruit fly is typically used because it is easy to care for, breeds quickly, lays many eggs, and its genetics is easy, because it contains only 4 pairs of chromosomes. Nowadays, Drosophila is getting more relevant because of the genetic resources developed such as balancer chromosomes, which come loaded with genetic markers for recessive mutation maintenance in a wild-type phenotype, and the inducible UAS/GAL4 system for space-temporal transgene expression that allows tissue-specific or developmental stage-specific gene expression [Duffy, 2002].
CoQ was detected firstly in the house fly (Musca domestica) presenting the isoform CoQ9 [Lester and Crane, 1959]. Other insects, like the ladybird Anatis ocellata, the caterpillar of hawk moth (Celerio euphorbiae), and Sphinx pinastri present mainly CoQ10 [Heller et al., 1960]. Incorporation of [5-3H]mevalonate into CoQ9 in embryonic cells of Drosophila suggested that it could produce CoQ9 [Havel et al., 1986]. Recently, it has been described that adult Drosophila contain both CoQ9 and CoQ10 [Cheng et al., 2011]. However, we analyzed different wild-type and mutant strains, and we found that Drosophila contains 3 CoQ isoforms (around 5% CoQ8, 82% CoQ9, and 13% CoQ10) with varying proportions depending on the developmental stage and age of the fly [Guerra et al., 2012].
Within the genes that take part in CoQ biosynthesis in Drosophila, qless (cg31005) is the orthologue of the human PDSS1 prenyl transferase that synthesizes the isoprenoid chain of CoQ (table 1). Neurons lacking qless upregulate markers of mitochondrial stress and undergo caspase-dependent apoptosis [Grant et al., 2010]. Dietary supplementation with CoQ10 rescued the neural phenotype of qless mutants.
The Drosophila homolog of COQ2 is encoded by the gene cg9613 which is called sbo (small boy), because mutations cause a small larval phenotype [Liu et al., 2011]. The sbo null mutants are developmentally arrested at the first instar larval stage and present about half of the ATP level of wild-type control larvae. Interestingly, sbo heterozygous animals complete their development, show reduced levels of CoQ (19% of CoQ9 and 65% of CoQ10 compared to wild-type flies), and present lifespan extension and a delayed aging phenotype due to the loss of negative geotaxis, a parameter whose loss accompanies aging in flies [Liu et al., 2011]. However, this result seems controversial because of the shorter lifespan shown by wild-type flies (around 1 month) compared to that published by other groups [Sanz et al., 2010] where wild-type flies reach at least 2-3 months of age.
Chromosomal deletions around the cg9613 (sbo, coq2) gene in Drosophila demonstrate that cg9613 mutant flies were more susceptible to bacterial and fungal infections, while they were more resistant to viruses [Cheng et al., 2011]. The gene expression of several anti-microbial peptides, like Diptericin B (DptB), Defensin (Def) and Drosomycin (Droso) which are specifically involved in the defense against fungi (Droso), Gram-negative (DptB and Def) and Gram-positive bacteria (Droso and Def), is drastically reduced in these mutants. Supplementation of food with CoQ10 restored the gene expression of these anti-microbial genes and thus the sensitivity to bacterial and fungal infections in coq2 mutants, although the resistance to viruses was lost [Cheng et al., 2011]. These results show that CoQ is necessary for the defense against bacteria and fungi, whereas it diminishes immune response against viruses, maybe because viruses need high levels of CoQ in the host to complete their life cycle, and they fail in CoQ-deficient flies.
Another attempt to mimic the CoQ deficiency syndrome in Drosophila was done interfering independently with the expression of each of the coq genes (table 1) with RNAi using the UAS-GAL4 system as shown in figure 2 [Fernandez-Ayala et al., 2012]. This technology needs the crossing of 2 parental flies to study gene silencing in the progeny: a parental fly carrying the RNAi against the coq gene of interest, which is under the control of both an Hsp (Heat-shock protein) minimal promoter and the enhancer sequence UAS that needs the transcription activator GAL4 bound to it to allow the transgene expression, and another parental fly carrying the GAL4 gene under the control of the daughterless (da) gene promoter, a gene that is widely expressed at low levels in all tissues during all developmental stages. For this experimental approach, flies were cultured at 3 different temperatures (29, 25, and 18°C) to generate stress conditions and different expression levels of the inductor GAL4 protein [Guerra et al., 2012].
Flies with RNAi against coq genes show a decrease in CoQ levels dependent on the affected gene and intensity of the gene silencing, with stronger disease phenotypes in flies cultured at 29°C under terminal stress and with higher GAL4 expression [Guerra et al., 2012]. Interestingly, RNAi against the cg10585 gene (pdss2, the regulatory subunit of COQ1) showed the most serious phenotype with developmental arrest just after egg hatching, and moreover, the few larvae presented morphological defects and improper development of the organs (fig. 3) as was previously described for coq-1 mutants in the worm C. elegans [Gavilan et al., 2005].
Gene interference of qless (cg31005/pdss1, the catalytic subunit of COQ1) produced lethality at an early larva stage, whereas RNAi against either coq2, coq3, coq5, coq7, coq8, coq9, or coq10 caused lethality at later larva stages or even at pupa stages [Guerra et al., 2012]. However, when the affected gene was coq6, flies managed to achieve adulthood but suffered a severe CoQ deficiency.
Remarkably, the silencing of the coq7 gene induced a severe reduction in the CoQ content at all developmental stages and the subsequent accumulation of DMQ, the intermediate compound in the CoQ biosynthesis that is the substrate of the COQ7 protein [Fernandez-Ayala et al., 2012]. Since Drosophila presented 3 species of CoQ (Q8, Q9, and Q10), the interference of coq7 accumulated DMQ for all of them. The mutant phenotype included pupa lethality at 25°C and around 20% of survival lowering the temperature to 18°C, although surviving flies presented developmental delay, reduced fertility, short lifespan, and higher reactive oxygen-species production during aging; mitochondrial preparations showed low oxygen consumption and a deficit in the electron transference of the respiratory chain. These results seem controversial to those shown by the clk-1 mutant C. elegans which had been amply described above. However, it is important to notice that clk-1 mutants present a point mutation that affects COQ7 almost at the end of the protein, and the gene silencing described here reduced the presence of coq7 mRNA to less than 10% [Fernandez-Ayala et al., 2012]. Additionally, DMQ was also detected when coq3, coq6, and coq9 were silenced, supporting the idea of a multi-enzymatic complex for CoQ biosynthesis, because loss of a component of such a complex could cause its instability and malfunction [Guerra et al., 2012].
Few other studies have been done with Drosophila, relating CoQ with several aspects of physiology and pathology. The removal of CoQ from the diet reduced lifespan and accelerates the aging process [Palmer and Sackton, 2003]. Since the common laboratory diet includes yeast, flies fed Q-less yeast were not long lived, whereas survival was higher in adults fed the wild-type yeast strain [Palmer and Sackton, 2003]. This result was similar to that published in the same work, where feeding flies with a yeast strain deficient in the mitochondrial respiratory complex III suggested that the mitochondrial functionality of the yeast diet, but not the absence of CoQ in the diet, was responsible for life shortening.
On the other hand, CoQ supplementation fails as an effective treatment for Parkinson's disease [Faust et al., 2009]. Inhibition of dj-1alpha (cg6646), the Drosophila homologue of the familial Parkinson's disease gene DJ-1, leads to oxidative stress, mitochondrial dysfunction, and dopaminergic neurons loss. CoQ10 supplementation showed no protective effect, while other drugs combining antioxidant and anti-inflammatory properties did.
Finally, either gene silencing with RNAi or deletions affecting any of the biosynthetic coq genes in D. melanogaster can be used as reliable models for human mitochondrial diseases with primary CoQ deficiency, allowing further studies on mitochondrial biogenesis during the development of a certain mitochondrial pathology but also on the therapy against neurodegeneration.
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