Next Article in Journal
A Quantum Chemical and Statistical Study of Cytotoxic Activity of Compounds Isolated from Curcuma zedoaria
Next Article in Special Issue
Understanding Xeroderma Pigmentosum Complementation Groups Using Gene Expression Profiling after UV-Light Exposure
Previous Article in Journal
Induction of Nickel Accumulation in Response to Zinc Deficiency in Arabidopsis thaliana
Previous Article in Special Issue
DNA Damage: A Sensible Mediator of the Differentiation Decision in Hematopoietic Stem Cells and in Leukemia
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Nucleotide Salvage Deficiencies, DNA Damage and Neurodegeneration

Colleges of Nanoscale Sciences and Engineering, State University of New York Polytechnic University, Albany, NY 12203, USA
*
Author to whom correspondence should be addressed.
Int. J. Mol. Sci. 2015, 16(5), 9431-9449; https://0-doi-org.brum.beds.ac.uk/10.3390/ijms16059431
Submission received: 2 January 2015 / Revised: 16 March 2015 / Accepted: 3 April 2015 / Published: 27 April 2015
(This article belongs to the Special Issue DNA Damage and Repair in Degenerative Diseases 2014)

Abstract

:
Nucleotide balance is critically important not only in replicating cells but also in quiescent cells. This is especially true in the nervous system, where there is a high demand for adenosine triphosphate (ATP) produced from mitochondria. Mitochondria are particularly prone to oxidative stress-associated DNA damage because nucleotide imbalance can lead to mitochondrial depletion due to low replication fidelity. Failure to maintain nucleotide balance due to genetic defects can result in infantile death; however there is great variability in clinical presentation for particular diseases. This review compares genetic diseases that result from defects in specific nucleotide salvage enzymes and a signaling kinase that activates nucleotide salvage after DNA damage exposure. These diseases include Lesch-Nyhan syndrome, mitochondrial depletion syndromes, and ataxia telangiectasia. Although treatment options are available to palliate symptoms of these diseases, there is no cure. The conclusions drawn from this review include the critical role of guanine nucleotides in preventing neurodegeneration, the limitations of animals as disease models, and the need to further understand nucleotide imbalances in treatment regimens. Such knowledge will hopefully guide future studies into clinical therapies for genetic diseases.

1. Introduction

Maintaining the appropriate level and balance of nucleotides is critical for DNA integrity and preventing neurodegeneration. Nucleotide levels are maintained in eukaryotes by de novo synthesis and nucleotide salvage; the latter mechanism is particularly important in neural cells (for review, see [1]). DNA damage triggers an increase in deoxynucleoside triphosphate (dNTP) levels, which is necessary for DNA repair mechanisms that require unscheduled DNA synthesis [2]. In model organisms, such as budding yeast, inability to increase dNTP levels after DNA damage exposure leads to higher frequencies of genetic instability [2]. Yeast cells that cannot maintain dNTP levels exhibit higher frequencies of spontaneous and DNA damage-associated petite colonies, due to mitochondrial dysfunction [3,4]. The mitochondrial genome is especially prone to damage due to incorporation of 8-oxo-deoxyguanosine triphosphate (8-oxo-dGTP), a mutagenic nucleotide resulting from oxidative stress. Similarly, insufficient dNTP levels result in mitochondrial and chromosomal instability in higher eukaryotic cells [5]. The purpose of this review is to correlate deficiencies in nucleotide salvage and synthesis with neurological and DNA metabolism defects.
Mutations in single genes encoding defective metabolic enzymes have been associated with neurological pathologies and purine nucleotide salvage, resulting in chronic gout, neurodegeneration, and odd behavioral pathologies, including self-mutilation by biting (for review, see [6]). Mitochondrial DNA depletion syndrome (MDS) has been associated with nine nuclear genes involved in the maintenance of mitochondrial dNTP pools, including thymidine kinase 2 (TK2), deoxyguanosine kinase (DGOUK), p53 dependent ribonucleotide reductase subunit 2 (RRM2B) and thymidine phosphorylase (TYMP); the most severe forms of the disease lead to infantile death (for review, see [7,8]). Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) is a rare autosomal disease that is associated with a defect in TYMP, but is late in onset; mitochondrial mutations are associated with ophthalmoparesis aberrant behavior. For example, Lesch-Nyhan syndrome (LNS) is a devastating, rare X-linked disease, in which defective, gastrointestinal dysmotility, peripheral neuropathy, and leukoencephalopathy occurs [9]. Although the deficient repair of DNA double-strand breaks and X-ray sensitivity are primarily associated with defects in ataxia telangiectasia mutated (ATM), ataxia telangiectasia (A-T) patients are defective in deoxycytosine salvage [10], and exhibit defective mitochondria [11], and cerebellar degeneration [12,13]. Underlying questions for each of these diseases concern the variation in severity of clinical pathologies and timing of onset, how mutations in the same gene can lead to different clinical presentations, and whether restoring dNTP levels or balance results in cure (Table 1). To understand these pathologies, it is worthwhile to review the role of dNTPs in neurological physiology, the basic biochemistry by which purine and dNTPs are salvaged and maintained, cellular defects that result when dNTPs are imbalanced, and mouse disease models. Elucidating the molecular defects can then guide strategies for gene therapy and possible drug treatments. This review explores current knowledge of how defects in nucleotide metabolism may associate with DNA damage and repair mechanisms in neurological tissue. In this review, we will discuss the historical background of nucleotide salvage and neurological disease, the biochemical control of pathways involved in nucleotide salvage and in maintaining dNTP levels, the checkpoint control of nucleotide salvage, insights from model organisms, recent mouse studies, and finally, discrepancies in the mouse and human models and future directions.
Table 1. Nucleotide metabolism genes and associated genetic defects.
Table 1. Nucleotide metabolism genes and associated genetic defects.
GeneDiseaseFrequencyMode of InheritanceEnzymatic DefectNeurophathy in Selected PatientsEffect on MitochondriaPathologies/Onset
HPRT1Lesch-NyhanRare, >300 alleles 1/380,000 live birthsX-linkedHypoxanthine guanine phosphoribosyl transferaseMotor functionIndirect production of free radicalsGout, diminished IQ, dystonia, Death due to hypotonia or renal failure
DGUOKMitochondrial depletion syndrome (MDS); hepatocerebral formExtremely Rare, 22 different mutations describedAutosomal recessiveDeoxy-guanosine kinaseHearing loss, nystagmusMitochondria depletion due to failure to produce substantial dGTPProgressive liver failure, patients generally die of liver failure in early childhood
TK2MDS (myopathic form)RareAutosomal recessiveThymidine kinase IIHypotonia, neurological featuresMitochondria depletion due to failure to salvage thymidine in mitochondriaMuscle weakness, extreme forms lead to respiratory failure and infantile death; mutations in less conserved aminoacids lead to progressive external ophthalmoplegia
Progressive external ophthalmoplegia (PEO)
TYMP (ECGF1)Mitochondrial neurogastroIntestinal encephalomyopathy (MNGIE)Rare, 50 different mutations have been describedSome domininant allelesThymidine phosphorylasePeripheral neuropathy, ophthalmoparesis, leukoencephalopathyMitochondrial depletionGastrointestinal dysmotility, weight loss; onset within first 20 years, 37 years the median age of death
RRM2BMDS (Encephalomyopathic form)RareRecessive alleles lead to severe MDS or MNGIE; dominant truncations confer PEOp53-induced ribonucleotide reductase B subunit (p53R2)Microcephaly,sensorineural hearing loss, ophthalmoplegiaMitochondria depletion; failure to repair UV damageSevere skeletal depletion of mitochondria, hypotonia and muscle weakness, sensorineural hearing loss, failure to thrive, lactic acidosis; mutations that confer PEO or MGIE are adult onset
PEO
MNGIE
ATMAtaxia Telangiectasia (A-T)RareAutosomal recessive ATMCerebellar ataxia Mitochondria less-well formedX-ray sensitivities, High frequencies of lymphoma/pulmonary infection
See references [7,8,9,10,11] for detailed discussions.
Nucleotide metabolism must be finely regulated in the nervous system, since although differentiated neuronal cells are non-cycling, there is high level of metabolism and large demand for ATP [14]. Whereas astrocytes are glycolytic and can produce lactate, neurons derive most of their energy through oxidative phosphorylation and can consume the lactate produced by astrocytes [15]. Thus, there is a demand for high mitochondrial copy number that depends on the replication and integrity of the 16.5 kb mitochondrial genome. However, cellular respiration catalyzed by oxidative phosphorylation can be an internal source of reactive oxygen species (ROS), which include superoxide anions, hydroxyl radicals, and hydrogen peroxide [16]. While ROS can directly damage DNA, they can also generate oxidized dNTPs, such as 8-oxo-dGTP, which can then be incorporated into either mitochondrial or genomic DNA, creating genetic instability [16,17]. Replication fidelity of polymerase γ, the mitochondrial DNA polymerase, is greatly affected by trace amounts of 8-oxo-dGTP [18]. Because mitochondria are involved in Ca2+ homeostasis, fatty acid metabolism, and pyrimidine nucleotide synthesis, mitochondrial dysfunction can lead to devastating pleiotropic effects and trigger apoptosis [19]. To maintain and balance dNTP levels, cells contain a specialized form of ribonucleotide reductase for de novo synthesis of dNTPs, encoded by RRM2B [20,21], and two specific salvage enzymes, thymidine kinase II (TK2) and deoxyguanosine kinase (dGK), which are located in the mitochondria.
Besides serving as energy co-factors and building blocks for RNA and DNA, nucleotides and bases also have critical roles in cell physiology as signaling molecules [22]. cAMP critically modulates the development of neuronal connectivity [23]. ATP is an important co-stimulator molecule in motor, sensory-motor, hypothalamus, parasympathetic and sympathetic nerves, functions in neuroprotection, and participates in neuro-regeneration from stem cells [23]. Guanosine modulates glutamatergic neurotransmission by stimulating glial reuptake of l-glutamate [24]. These examples illustrate that nucleotides can also serve as signaling molecules in order to facilitate neural synapses.

2. Biochemistry of de Novo and Salvage Pathways for Nucleotide Biosynthesis in the Nervous System

Because there is a dynamic pool of dNTPs, dNTPs must be continually synthesized and degraded. dNTPs can also be recycled from free bases resulting from RNA or DNA turnover. Since terminally differentiated neurons do not replicate, in order to maintain nucleotide levels and balance there is greater reliance on salvage pathways compared to de novo synthesis [6]. In de novo synthesis, purine and pyrimidine ribonucleotides are made from basic constituents; these include phosphoribosyl pyrophosphate (PRPP), glutamine, and glycine for purine nucleotides, and carbamoyl phosphate, aspartate, and PRPP for pyrimidine biosynthesis. The key regulated enzyme in de novo purine biosynthesis is glutamine PRPP amidotransferase, which is feedback inhibited by the ribonucleotide monophosphates, adenylate (AMP), inosylate (IMP), and guanylate (GMP), and positively activated by PRPP (Figure 1).
Pyrimidine de novo biosynthesis is generally regulated at the step of carbamoyl phosphate synthetase, and key initial enzymatic reactions are encoded in one large cytoplasmic polypeptide, composed of carbomoyl phosphate synthetase, aspartate transcarbamoylase, and dihyrooratase (CAD, for general information concerning nucleotide biosynthesis, see [25]).
Figure 1. Outline of purine de novo synthesis, salvage, and degradation. Red arrows indicate sysnthesis, and blue arrows indicate salvage. Black arrows indicate the conversion of nucleotides to nucleosides and bases, and the conversion of nucleosides to nucleotides. Phosphoribosyl pyrophosphate (PRPP) is inhibited by adenylate (AMP), inosylate (IMP), and guanylate (GMP), as indicated.
Figure 1. Outline of purine de novo synthesis, salvage, and degradation. Red arrows indicate sysnthesis, and blue arrows indicate salvage. Black arrows indicate the conversion of nucleotides to nucleosides and bases, and the conversion of nucleosides to nucleotides. Phosphoribosyl pyrophosphate (PRPP) is inhibited by adenylate (AMP), inosylate (IMP), and guanylate (GMP), as indicated.
Ijms 16 09431 g001
Ribonucleoside diphosphates (NDPs) are made and then converted to deoxynucleoside diphosphates (dNDPs) by reduction catalyzed by the allosteric enzyme ribonucleotide reductase (RNR, [21]). RNR is a tetramer composed of two small subunits, which contain the catalytic site, and two large subunits, which contain the substrate binding sites for NDPs, as well as regulatory binding sites for deoxyadenosine triphosphate (dATP), deoxythymidine triphosphate (dTTP), and deoxyguanosine triphosphate (dGTP) [21]. While dATP allosterically acts to inhibit the activity of RNR, dTTP allosterically activates the conversion of purine ribonucleotides and allosterically inhibits the conversion of cytosine diphosphate CDP. RNR subunits are regulated at the level of transcription, translation, and post-translational modification to ensure that essential dNTPs meet the demand of DNA synthesis [21].
In neural tissue, salvage pathways are important to maintain the nucleotide balance, and the utilization of de novo pathways diminish towards adulthood. The free purine bases, hypoxanthine and guanine, can be salvaged by hypoxanthine guanine phosphoribosyl transferase (HGPRT). The products of HGPRT include the PRPP amidotransferase allosteric inhibitors IMP, GMP, AMP. The reaction also utilizes the substrate PRPP, the allosteric positive activator or PRPP amidotransferase. Thus, HGPRT salvages bases while at the same time reducing de novo synthesis of purine nucleotides by increasing the concentration of inhibitory nucleotides and decreasing the concentration of PRPP. HGRPT phosphoribosyl transferase is located in the nervous system and is found in abundance in the brain [26].
Salvage pathways for deoxynucleotides do not involve phosphoribosyl transferases, but instead involve kinases that convert nucleosides to nucleotides (Figure 2). The thymine salvage pathway generating thymidylate involves nucleoside phosphorylase, which can catalyze either the production of the nucleoside or of the base and sugar, which could then be degraded. However, in the presence of thymidine kinase, thymidylate (TMP) synthesis shifts the catalysis towards thymine salvage. Similarly, guanosine kinase and cytidine kinase can generate deoxyguanylate (dGMP) and deoxycytidylate (dCMP), respectively [27].
Figure 2. Key steps in the salvage of deoxynucleotides in the mitochondria. Arrows designate the steps in the salvage pathways; a dashed arrow indicates import into the mitochondria, and a blue arrow indicates degradation. The large oval (blue) is the mitochondria, the small oval (black) represents the p53-regulated ribonucleotide reductase (p53R2/R1). The nucleotides in the mitochondria include thymidylate (TMP), thymidine diphosphate (TDP), thymdine triphosphate (TTP), deoxyguanosine monophosphate (dGMP), deoxyguanosine diphosphate (dGDP), and deoxyguanosine triphosphate (dGTP). Thymidine kinase II (TK2) and deoxyguanosine kinase (dGK) are salvage enzymes.
Figure 2. Key steps in the salvage of deoxynucleotides in the mitochondria. Arrows designate the steps in the salvage pathways; a dashed arrow indicates import into the mitochondria, and a blue arrow indicates degradation. The large oval (blue) is the mitochondria, the small oval (black) represents the p53-regulated ribonucleotide reductase (p53R2/R1). The nucleotides in the mitochondria include thymidylate (TMP), thymidine diphosphate (TDP), thymdine triphosphate (TTP), deoxyguanosine monophosphate (dGMP), deoxyguanosine diphosphate (dGDP), and deoxyguanosine triphosphate (dGTP). Thymidine kinase II (TK2) and deoxyguanosine kinase (dGK) are salvage enzymes.
Ijms 16 09431 g002
The degradation of nucleotides is important in maintaining nucleotide pools [27]. Generally pyrimidine nucleotides are degraded by nucleotidases and nucleoside phosphorylases, which cleave the base from the sugar; the pyrimidine bases can be completely degraded to CO2 and H2O. However, purine bases cannot be completely degraded and the ultimate end product is uric acid (Figure 1). Guanine nucleotides are degraded to hypoxanthine and xanthine, respectively. Hypoxanthine and xanthine are substrates of xanthine oxidase, generating hydrogen peroxide and uric acid. Thus, overactive xanthine oxidase leads to excess uric acid and the production of ROS [28]. Uric acid has low solubility in the blood, and uric acid crystals can trigger gout resulting from extreme inflammation [29] (Figure 1).
Deoxynucleotide pools in the mitochondria are maintained by both cytoplasmic de novo enzymes and salvage enzymes located with the mitochondria (Figure 2). In general, mitochondrial deoxynucleotide levels are approximately ten-fold lower than levels measured from the cytoplasm [30,31,32,33]. A cytoplasmic ribonucleotide reductase which is not found in cycling cells is found in neuronal tissue in which the small subunit R2 is substituted by the p53R2 [20].
Nucleotide transporters then shuttle nucleotides into the mitochondria. In addition, the mitochondrial forms of guanosine kinase and thymidine kinase, although encoded by nuclear genes, are active in the mitochondria. Interestingly, mRNA expression of deoxyguanosine kinase is highest in muscle, brain, liver, and lymphoid tissues, where there is high demand for mitochondrial function. Measurements of mitochondrial dNTP concentrations in human fibroblasts and liver indicate that dGTP is the most abundant dNTP [30,31,32,33], and that much of the dGTP is derived, however, from the de novo synthesis catalyzed in the cytoplasm [34]. These studies have indicated that both ribonucleotide reductase and salvage enzymes contribute to maintaining deoxynucleotide levels in the mitochondria.

3. Human Diseases Resulting from Defective Nucleotide Metabolism

3.1. Lesch-Nyhan Disease

Lesch-Nyhan syndrome (LNS), first reported in 1964 [6], affects 1/380,000 live births and is due to mutations in the X-linked HPRT1 gene, resulting in defective hypoxanthine guanine phosphoribosyl (HPRT) transferase activity [6,34]. Over three hundred alleles have been described, some of which result from large deletions due to recombination between Alu repeats [34,35]. The disease has three major characteristics: (1) overproduction of uric acid; (2) motor and cognitive disability; and (3) self-injuring behavior. The neurological and behavioral symptoms of the disease are less severe in some cases, and molecular genetics suggest that this may depend on the residual HPRT activity; however all forms are characterized by chronic over-production of uric acid. Extreme neurological defects include an inability to walk [36,37]. Patients have a shorter life span, and mortality is generally due to renal failure and hypotonia in the first or second decade of life; however, less severe cases may have longer lifespans [24,36].
The behavior and neurological symptoms have puzzled clinicians since the inherited disease is closely linked to a single metabolic defect in purine nucleotide salvage. Treatment with allopurinol that inhibits xanthine oxidase does reduce plasma uric acid levels but does not alleviate the neurological symptoms. A breakthrough was reported by observations that LNS patients have abnormally few dopaminergic nerve terminals [38]. The abnormality involves all dopaminergic pathways and is not restricted to the basal ganglia, as confirmed by positron emission tomography (PET) scans [39]. The developmental nature of the origin of the dopaminergic deficits suggests that these defects may explain both the behavioral and neurological symptoms of the disease [38].
There is no clear explanation for how the scarcity of dopaminergic nerve terminals results from the purine salvage defect. One hypothesis is based on the observations that because of the purine salvage deficiency, cells produce high levels of hypoxanthine but lower levels of GTP. Since GTP is the precursor of tetrahydrobiopterin (BH4) and conversion of tyrosine to dopamine requires BH4, dopamine synthesis may be insufficient [40,41]. In addition, high levels of hypoxanthine may be toxic to neurotransmission since hypoxanthine can bind to the benzodiazepine agonist recognition site on the γ-aminobutyric acid-A (GABA-A) receptor complex [40]. These data thus indicate that multiple mechanisms could adversely affect neurological function due to nucleotide imbalance.
Several studies suggest that LNS patients are defective in DNA repair [42,43]. ATP-ribose activity is diminished in fibroblasts derived from LNS, and would affect base excision DNA repair mechanisms, which are important for maintaining mitochondria. Additional experiments using HPRT-defective pluripotent ESD3 murine embryonic stem cells demonstrate that the transcriptional profile of the differentiating stem cells show down regulation of DNA repair and cell cycle genes, as well as a shift in the developmental profile from neuronal to a glial pattern [44]. These studies indicate that multiple signaling pathways that affect neuronal development may be altered in LNS patients and that the complex neurological and behavioral symptoms may be due to a combination of factors resulting from nucleotide imbalance [45,46,47,48].

3.2. Mitochondrial Depletion Syndromes (MDS)

The rare autosomal recessive mitochondrial deletion syndromes (MDS) include a range of genetic defects that share in common the depletion of mitochondrial DNA. Among this group are several diseases that affect deoxynucleotide salvage and de novo synthesis [48,49]. The three main clinical forms of MDS, myopathic, encephalomyopathic and hepatocerebral, are defined through the tissues that they affect. Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) affects the gastrointestinal tract [48,49]. Progressive external ophtalmoplegia (PEO) is the paralysis or weakness of the eye muscles [43,49,50]. Although many of these diseases may result in early childhood death, the clinical severity may correlate with the biochemical defect.
The hepatocerebral form of MDS resulting from mutations in the gene encoding deoxyguanosine kinase (dGUOK) [51], is a rare recessive autosomal disease with devastating clinical effect [50]. Twenty-two point mutations, deletions and insertions in dGUOK have been reported [52,53]. Friesinger et al. reported six patients with mutations in dGUOK [54]. Symptoms include dGUOK-related neonatal hepatic dysfunction, such as lactic acidosis and hypoglycemia, and neurological dysfunction, including psychomotor delay, hypotonia, and rotary nystagmus [50]. Individual patients have also been noted to experience progressive hearing loss. Most patients die in early childhood due to liver failure, although a few have been noted to survive into teen years [54]. Measurements of mitochondrial dGTP levels from fibroblasts of affected patients demonstrate that the reduction in dGTP correlates with the loss of mitochondrial copy number [55]. These studies thus support the notion that although dGTP is made through both de novo and salvage pathways, the salvage pathway is necessary to maintain mitochondrial DNA copy number.
Several diseases result from defects in enzymatic steps in thymidine salvage, including thymidine kinase II and thymidine phosphorylase [32]. Thymidine kinase II is critical for mitochondrial maintenance but the deficiency is myopathic and patients exhibit severe skeletal muscle weakness; infantile death generally results from respiratory failure [56,57]. However, substitutions at less-conserved amino acids, T230A and R225W, results in PEO, which is late in onset [56].
Thymidine phosphorylase deficiency is the cause of MNGIE [9,58,59], an extremely rare autosomal recessive disease. The clinical symptoms include gastrointestinal dysmotility, cachexia, ophthalmoparesis, and peripheral neuropathy [9,58]. Onset is generally within the first twenty years, although late-onset cases have also been reported. There is generally great variability in the pathology of the disease, even among siblings [59]. Missense mutations in thymidine phosphorylase correlate with late-onset MNGIE. Due to the onset of the disease in young adults, it can be misdiagnosed as anorexia. Onset of death often occurs in middle age (30–40 years) [9,58,59].
Interestingly, plasma deoxythymidine levels are elevated in MNGIE patients, while cellular mitochondrial DNA is depleted [60]. The progression of the disease correlates with mitochondrial DNA instability; however, elevated deoxypyrimidine levels may not correlate with affected tissues [60]. Although it is unclear why elevated levels of deoxythymidine would correlate with mitochondrial instability, recent reports suggest that mitochondrial concentrations of dCTP levels are depleted. To date, there is no proven treatment for the disease [61]. Dialysis can lessen the clinical burden of toxic nucleosides. Recently a number of clinics have proposed to restore thymidine phosphorylase activity through cell transplantation using allogeneic hematopoetic stem cells to restore thymidine phosphorylase activity [62].
As well as being conferred by defects in TK II, PEO can also result from mutations in RRM2B; RRM2B is the gene that encodes the subunit of ribonucleotide reductase, p53R2, which is associated with ribonucleotide reductase in non-cycling cells. Mutations that delete p53R2 lead to early onset fatal depletion of mitochondrial DNA [63,64,65]. However, compound p53R2 alleles can confer MNGIE [64,65]. A dominant allele RRM2B was observed to confer an adult-onset PEO with multiple mitochondrial lesions [66]. These observations indicate that RRM2B is essential for mitochondrial DNA maintenance, but, depending on the allele, late onset disease may result.

3.3. Ataxia Telangietasia (A-T)

A-T is an autosomal recessive disease that has a broad spectrum of disease phenotypes; the incidence is 1/40,000 in the United States [12,13]. These include hypersensitivity to X-rays, cerebellar neuronal degeneration, cancer susceptibility, and immunodeficiency. A-T patients may also have complicated secondary clinical presentations [11,12]. The cellular phenotypes of A-T are complex: besides high frequencies of chromosomal abnormalities, there are also mitochondrial dysfunctions and cytoskeletal abnormalities [11,12]. These complex cellular phenotypes may contribute to the neurodegeneration and ataxia that afflicts A-T patients.
The ATM kinase is a dimer that phosphorylates a large number of substrates and regulates cell cycle progression at G2. The ATM kinase not only is found in the nucleus, but also in the cytoplasm in differentiated non-proliferating neurons and in Purkinje cells. Disruption of ATM signaling leads to disruption of ribonucleotide reductase’s ability to upregulate mitochondrial DNA synthesis after ionizing radiation exposure, and early passage of A-T fibroblasts show 50% lower levels of mitochondria, perhaps due to faulty regulation of ribonucleotide reductase [67]. Eaton et al. [67] suggest that ATM-induced regulation of ribonucleotide reductase is essential for mitochondrial biogenesis. ATM also contributes to maintaining dNTP levels by nucleotide salvage. ATM can phosphorylate deoxycytidine kinase, thereby shifting the kinase substrate specificity towards deoxycytidine to maintain dNTP pools [10]. Thus, A-T could also contribute to mitochondrial stability through upregulating ribonucleotide reductase and maintaining dNTP balance when cells are exposed to agents that cause double-strand breaks.

4. Animal Models

Animal models are useful in untangling the complexities of disease phenotypes that are conferred by human metabolic syndromes in nucleotide metabolisms (see Table 2, for summary), as well as testing for potential therapeutic interventions that could restore deoxynucleotide balance and mitochondria [44]. Such complexities include the tissue specificities of genetic defects and disease onset and penetrance. Since biochemical pathways and genes in nucleotide metabolism are essentially conserved between rodents and man, it is now possible to create humanized mice that express particular disease-associated alleles of nucleotide biosynthetic genes.

4.1. Mouse Models for Lesch-Nyhan Syndrome

Hprt−/− Mice

Targeted deletion of Hprt in mice (Hprt−/−) does not give rise to any behavioral phenotypes suggestive of the characteristics of Lesch-Nyhan syndrome, namely mental retardation and the pathological self-mutilation [68,69]. Furthermore, despite having no detectable HPRT enzyme activity in the brain, these mice have normal brain purine content, an effect that was attributed to an increase in de novo purine synthesis [69], which also renders the mice hyperuricemic. Abnormal purine content has been noted for specific cell types, such as the astrocytes [70,71], and mutant mice exhibit age-related decrease in dopamine content in the brain [71]. It is important to note that other pathogenic human variants of HPRT have been documented that are associated with a less severe manifestation of Lesch-Nyhan syndrome; therefore, in any animal model of LNS, residual HPRT enzyme activity should be an important consideration when interpreting phenotypes [72].

4.2. Mouse Models for MDS Linked to Thymidine Kinase Deficiency

Tk2−/− Mice

Homozygous deletion of Tk2 in mice (Tk2−/−) results in complete postnatal lethality between 2–4 weeks of life with multiple organ systems affected, likely due to organism-wide cellular mitochondrial defects including decreased mitochondrial DNA and abnormal crista morphology [73]. Another Tk2 targeted mouse carrying an amino acid substitution (Tk2H126N) found in a pediatric patient with MDS may represent a better model for this disease; similar to the Tk2−/− mouse, it displays complete postnatal lethality and mitochondrial defects, but there are also clear manifestations of neurological malfunction including tremors, weakness, decreased activity and altered gait [74].
Point mutations or deletions in mitochondrial DNA are not observed in Tk2−/− mice, perhaps due to the depletion of intracellular thymidine and subsequent cessation of mitochondrial DNA replication [75]. By day fourteen, mitochondrial DNA is depleted in skeletal muscle, heart, liver, adipose and spleen, thus affecting both resting and replicating tissue [75]. There is active investigation into whether the TK2 defect can be rescued by gene therapy; over-expression of TK2 in the mouse models extends the life span of Tk2−/− mice from three weeks to twenty months, suggesting that some clinical features of the disease might be reversible [76].
Table 2. Mouse models for human genetic defects in nucleotide salvage and metabolism.
Table 2. Mouse models for human genetic defects in nucleotide salvage and metabolism.
DiseaseGeneMouse GenotypePhenotypes
NeurologicalDNA Damage SensitivityOther
Lesch-NyhanHGPRT1Hprt−/−None reportedNone reportedHyperuricemia
MDSTK2Tk2−/−None reportedNone reportedPost-natal mortality (2–4 weeks); growth retardation; cellular mitochondrial defects; hypothermia due to the absence of subcutaneous adipose tissue; abnormal morphologies of brown adipocytes, myocardiocytes and hepatocytes
MDSTK2TKH126N (knock-in)Encelphalopathy; tremors; weakness; decreased activity; altered gait None reportedPost-natal mortality with defects similar to that of Tk2−/− mice
MNGIETYMP (ECGF1)TP−/−; UP−/−Encephalopathy; abnormal myelin sheath morphology; mitochondrial DNA instability in the brainNone reportedElevated plasma thymidine; defects in nucleotide homeostasis and enzyme/coenzyme metabolism
MDSRRM2BRrm2b−/−Abnormal sciatic nerve morphologyHigher rates of spontaneous mutation in the kidneyRenal organ failure at 14 weeks
Ataxia telangiectasiaATMAtm−/−Abnormal neuronal cell morphologies; neuronal cell degenerationHypersensitivity to gamma radiation; abnormal cell cycle checkpoint response; spontaneous lymphomasGrowth retardation; premature death; decreased thymocyte numbers; infertility in both sexes
TK2 is thymidine kinase 2; TYMP is thymidine phosphorlase; RRM2B is the gene encoding p53R2, a small subunit of ribonucleotide reductase that binds p53; ATM is the human gene “Mutated in ataxia telangiectasia”; MNGIE refers to mitochondrial neurogastrointestinal encephalomyopathy; TP is the gene encoding thymidine phosphorylase; UP is the gene encoding uridine phosphorylase.

4.3. Mouse Models for Mitochondrial Neurogastrointestinal Encephalomyopathy (MNGIE)

TP−/− and UP−/− Mice

Targeted deletion of thymidine phosphorylase (TP) in mice was hypothesized to give rise to an increase in plasma levels of thymidine and the disease pathologies associated with mitochondrial neurogastrointestinal encephalomyopathy (MNGIE). This hypothesis was not completely born out since the TP−/− mice have only modest increases in plasma thymidine and TP activity is maintained in the small intestine, likely due the compensatory action of uridine phosphorylase, which in mice has the ability to cleave both thymidine and uridine [76]; therefore, Lopez et al. [76] generated a TP and uridine phosphorylase UP double knock-out mouse (TP−/−; UP−/−), which did indeed increase the plasma levels of thymidine over those observed in the TP−/− single knockout mouse. Furthermore, TP−/−; UP−/− exhibit similar pathologies as human MNGIE patients.

4.4. Mouse Models for p53R2 Deficiency and Over-Expression of Ribonucleotide Reductase (RNR) Subunits

Rrm2b−/− Mice

The supply of cellular deoxyribonucleotides (dNTPs) pools is generated through the activity of multi-subunit ribonucleotide reductase enzymes, and p53R2 is a small subunit of this complex. To determine the role of this individual subunit in dNTP supply, Kimura et al. [77] generated a homozygous knock out mouse for Rrm2b (Rrm2b−/−) and found that the mice develop normally until they are weaned, after which they become severally growth retarded and die prematurely. Pathological features associated with this early mortality phenotype included increased DNA damage in the kidney and severe renal failure by the age of 14 weeks, suggesting that p53R2 is required for maintaining DNA-repair related dNTP pools in some organs [64]. Another intriguing link between p53R2, dNTP pools and the mitochondria emerged from a study that identified several mutations of the RRM2B in unrelated individuals with MDS, suggesting that p53R2 activity is also important for mtDNA replication [64].
Over-expression of p53R2 by gene therapy has been suggested as a means to increase levels of dNTPs in non-proliferating cells and restore mitochondria in Rrm2b−/− mice. Over-expression of RNR subunits, Rrm1, Rrm2, and p53R2, in transgenic mice, however, does not increase mitochondrial copy number, but instead leads to depletion of mitochondria [78]. Yikallio et al. [78] hypothesize that depletion of mitochondria in transgenic mice results from dNTP imbalance and show that ratios of dNTPs in mouse skeletal muscle are imbalanced, compared to wild type. These studies show that although p53R2 is necessary for maintaining dNTP levels, it is not sufficient.

4.5. A-T Mouse Models and Neurodegeneration

A-T mouse knockouts have been intensely studied. A-T mutant mice mimic human conditions, namely radiosensitivity, immunodeficiency, and cancer predisposition [79]. Although A-T mice do exhibit neurological abnormalities and have behavioral phenotypes, they do not exhibit progressive neurodegeneration. Cells from A-T mice appear to be under constant stress and exhibit high levels of the transcription factor activator protein-1 (AP-l) [80]. These studies indicate that although it is possible to mimic the DNA repair defect, it is not yet possible to mimic the neurodegenerative defect in the A-T mouse model [80].

5. Summary and Future Directions

DNA repair and nucleotide salvage mechanisms play an important role in preventing neurodegenerative disease. The purpose of this review was to consider how dNTP balance is maintained in nervous tissues, and how lack of salvage pathways leads to neurodegenerative diseases, resulting from DNA mutation. The primary conclusion is that nucleotide imbalance can lead to a wide variety of neurodegenerative diseases resulting from multiple changes in neural physiology. MDS diseases and associated neurological syndromes show clear correlation with deficiencies in mitochondrial dNTP levels, which lead to neurodegeneration resulting from defective mitochondrial DNA replication. On the other hand, LNS diseases, although linked to a single defect in nucleotide salvage, have complicated symptoms in which DNA repair has only recently been associated with metabolism.
Of the diseases discussed, both LNS and the hepatocerebral form of MDS resulting from mutations in dGUOK have the most severe neurological symptoms. Both involve salvage of guanine and illustrate the importance of guanine nucleotides in maintaining the physiology and the genetic integrity of the nervous system. Recent studies have suggested that HPRT1 functions in multiple housekeeping roles, including cell cycle and DNA repair [44]. It is important to note that neurological presentations are manifested in patients that have the most severe HPRT deficiencies, although further study is necessary to match genotype with disease progression [34].
MNGIE patients exhibit a wide variety of symptoms; the disease is later in onset than many MDS patients afflicted with the hepatocerebral form. Since the fidelity of mitochondrial replication is severely compromised when the mitochondrial nucleotide pool is insufficient or imbalanced, it is likely that defects resulting in the most imbalanced nucleotide pools confer an early and severe disease onset. Factors that account for the variable disease manifestations of MNGIE have not been fully elucidated. While the pathology was first thought to result from excess levels of deoxythymidine and deoxyuridine [60], it is now apparent that other nucleotides, such as dCTP, are actually deficient and may contribute to neurodegeneration [61]. These studies illustrate that understanding the broad spectrum of nucleotide imbalance may be necessary in unraveling the complexities of MNGIE.
Animal rodent models have limitations when studying late or gradual onset neurological degeneration but do show promise in studying genetic alleles. One interesting similarity between humans and mice is that many of the defects in nucleotide salvage do not present a phenotype until after weaning; this suggests that an alternative source of dNTPs may be available, such as a maternal source. However animal models also have limitations in understanding disease phenotypes. First, life span is shorter, so neurological defects that take years to develop in humans may not be manifested. Second, mice have higher levels of plasma thymidine and uridine, so the incremental increase in dNTPs resulting from genetic defects may have different physiological results.
The apparent “cure” for the diseases is to “correct” the genetic defects by increasing the insufficient nucleotide levels and restoring nucleotide pools. Indeed, increasing nucleotide pools appears sufficient to minimize genetic instability phenotypes in budding yeast mutants with defective deoxynucleotide levels [81]. Although increasing overall levels of deoxynucleotides appears sufficient to increase mitochondrial genomes in budding yeast [82], similar experiments in transgenic mice have not yielded the same results [64]. Some attempts to alleviate neurological symptoms of LNS patients by administration of S-adenosyl methione resulted in one published report of a positive outcome [83]. However, with the advent of stem cell technologies, new efforts are focusing on whether enzymatic deficiencies can be restored, using emerging transplant therapies [84].

Acknowledgments

We would like to acknowledge Cinzia Cera for assistance in preparing this manuscript. This work was supported by National Institutes of Health (R15ES02685).

Author Contributions

Michael Fasullo contributed the information concerning nucleotide salvage pathways, DNA repair phenotypes, and human diseases. Lauren Endres contributed information concerning mouse disease phenotypes.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Micheli, V.; Camici, M.; Tozzi, M.G.; Ipata, P.L.; Sestini, S.; Bertelli, M.; Pompucci, G. Neurological disorders of purine and pyrimidine metabolism. Curr. Top. Med. Chem. 2011, 11, 923–947. [Google Scholar] [CrossRef] [PubMed]
  2. Chabes, A.; Bilyana, G.; Domkin, V.; Zhao, X.; Rothstein, R.; Thelander, L. Survival of DNA damage in yeast directly depends on increased dNTP levels allowed by relaxed feedback inhibition of ribonucleotide reductase. Cell 2003, 112, 391–401. [Google Scholar] [CrossRef] [PubMed]
  3. Fasullo, M.; Koudelik, J.; AhChing, P.; Giallanza, P.; Cera, C. Radiosensitive and mitotic recombination phenotypes of the Saccharomyces cerevisiae dun1 mutant defective in DNA damage-inducible gene expression. Genetics 1999, 152, 909–919. [Google Scholar]
  4. Fikus, M.U.; Mieczkowski, P.A.; Koprowski, P.; Rytka, J.; Sledziewska-Gójska, E.; Ciésla, Z. The product of the DNA damage-inducible gene of Saccharomyces cerevisiae, DIN7, specifically functions in mitochondria. Genetics 2000, 154, 73–81. [Google Scholar] [PubMed]
  5. Weinberg, G.; Ullman, B.; Martin, D.W. Mutator phenotypes in mammalian cell mutants with distinct biochemical defects and abnormal deoxyribonucleoside triphosphate pools. Proc. Natl. Acad. Sci. USA 1981, 78, 2447–2451. [Google Scholar] [CrossRef]
  6. Fu, R.; Ceballos-Picot, I.; Torres, R.J.; Larovere, L.E.; Yamada, Y.; Nguyen, K.V.; Hegde, M.; Visser, J.E.; Schretlen, D.J.; Nyhan, W.L.; et al.; Lesch-Nyhan Disease International Study Group Brain. Genotype–phenotype correlations in neurogenetics: Lesch-Nyhan disease as a model disorder. Brain 2014, 137, 1282–1303. [Google Scholar] [CrossRef] [PubMed]
  7. Nogueira, C.; Almeida, L.S.; Nesti, C.; Pezzini, I.; Videira, A.; Vilarinho, L.; Santorelli, F.M. Syndromes associated with mitochondrial DNA depletion. Ital. J. Pediatr. 2014, 40, 34. [Google Scholar] [CrossRef] [PubMed]
  8. Copeland, W.C.; Longley, M.J. Mitochondrial genome maintenance in health and disease. DNA Repair 2014, 19, 190–198. [Google Scholar] [CrossRef] [PubMed]
  9. Nishino, I.; Spinazzola, A.; Hirano, M. Thymidine phosphorylase gene mutations in MNGIE, a Human Mitochondrial Disorder. Science 1999, 283, 689–692. [Google Scholar] [CrossRef] [PubMed]
  10. Bunimovich, Y.L.; Nair-Gill, E.; Riedinger, M.; McCracken, M.N.; Cheng, D.; McLaughlin, J.; Radu, C.G.; Witte, O.N. Deoxycytidine kinase augments ATM-mediated DNA repair and contributes to radiation resistance. PLoS ONE 2014, 9, e104125. [Google Scholar] [CrossRef] [PubMed]
  11. Sharma, N.K.; Lebedeva, M.; Thomas, T.; Kovalenko, O.A.; Stumpf, J.D.; Shadel, G.S.; Santos, J.H. Intrinsic mitochondrial DNA repair defects in Ataxia Telangiectasia. DNA Repair 2014, 13, 22–31. [Google Scholar] [CrossRef] [PubMed]
  12. Ambrose, M.; Gatti, R.A. Pathogenesis of ataxia-telangiectasia: The next generation of ATM functions. Blood 2013, 121, 4036–4045. [Google Scholar] [CrossRef] [PubMed]
  13. Pollard, J.M.; Gatti, R.A. Clinical radiation sensitivity with DNA repair disorders: An overview. Int. J. Radiat. Oncol. Biol. Phys. 2009, 74, 1323–1331. [Google Scholar] [CrossRef] [PubMed]
  14. Federico, A.; Cardaioli, E.; da Pozzo, P.; Formichi, P.; Gallus, G.N.; Radi, E. Mitochondria, oxidative stress and neurodegeneration. J. Neurol. Sci. 2012, 322, 254–262. [Google Scholar] [CrossRef] [PubMed]
  15. Bélanger, M.; Allaman, I.; Magistretti, P.J. Brain energy metabolism: Focus on astrocyte-neuron metabolic cooperation. Cell Metab. 2011, 14, 724–738. [Google Scholar] [CrossRef] [PubMed]
  16. Furda, A.M.; Marrangoni, A.M.; Lokshin, A.; van Houten, B. Oxidants and not alkylating agents induce rapid mtDNA loss and mitochondrial dysfunction. DNA Repair 2012, 11, 684–692. [Google Scholar] [CrossRef] [PubMed]
  17. Scheibye-Knudsen, M.; Fang, E.F.; Croteau, D.L.; Wilson, D.M., 3rd; Bohr, V.A. Protecting the mitochondrial powerhouse. Trends Cell Biol. 2014, 25, 158–170. [Google Scholar] [CrossRef] [PubMed]
  18. Pursell, Z.F.; McDonald, J.T.; Mathews, C.K.; Kunkel, T.A. Trace amounts of 8-oxo-dGTP in mitochondrial dNTP pools reduce DNA polymerase gamma replication fidelity. Nucleic Acids Res. 2008, 36, 2174–2181. [Google Scholar] [CrossRef] [PubMed]
  19. Desler, C.; Lykke, A.; Rasmussen, L.J. The effect of mitochondrial dysfunction on cytosolic nucleotide metabolism. J. Nucleic Acids 2010, 2010, 701518. [Google Scholar] [CrossRef] [PubMed]
  20. Pontarin, G.; Ferraro, P.; Bee, L.; Reichard, P.; Bianchi, V. Mammalian ribonucleotide reductase subunit p53R2 is required for mitochondrial DNA replication and DNA repair in quiescent cells. Proc. Natl. Acad. Sci. USA 2012, 109, 13302–13307. [Google Scholar] [CrossRef] [PubMed]
  21. Nordlund, P.; Reichard, P. Ribonucleotide reductases. Annu. Rev. Biochem. 2006, 75, 681–706. [Google Scholar] [CrossRef] [PubMed]
  22. Abbracchio, M.P.; Burnstock, G.; Verkhratsky, A.; Zimmermann, H. Purinergic signalling in the nervous system: An overview. Trends Neurosci. 2009, 32, 19–29. [Google Scholar] [CrossRef] [PubMed]
  23. Averaimo, S.; Nicol, X. Intermingled cAMP, cGMP and calcium spatiotemporal dynamics in developing neuronal circuits. Front. Cell. Neurosci. 2014, 8, 376. [Google Scholar] [CrossRef] [PubMed]
  24. Deutsch, S.I.; Long, K.D.; Rosse, R.B.; Mastropaolo, J.; Eller, J. Hypothesized deficiency of guanine-based purines may contribute to abnormalities of neurodevelopment, neuromodulation, and neurotransmission in Lesch-Nyhan syndrome. Clin. Neuropharmacol. 2005, 28, 28–37. [Google Scholar] [CrossRef] [PubMed]
  25. Nelson, D.L.; Lehninger, A.L.; Cox, M.M. Lehninger Principles of Biochemistry, 5th ed.; Ch WH Freeman and Company: New York, NY, USA, 2008; pp. 882–900. [Google Scholar]
  26. Ceballos-Picot, I.; Mockel, L.; Potier, M.C.; Dauphinot, L.; Shirley, T.L.; Torero-Ibad, R.; Fuchs, J.; Jinnah, H.A. Hypoxanthine-guanine phosphoribosyl transferase regulates early developmental programming of dopamine neurons: Implications for Lesch-Nyhan disease pathogenesis. Hum. Mol. Genet. 2009, 18, 2317–2327. [Google Scholar] [CrossRef] [PubMed]
  27. Rampazzo, C.; Miazzi, C.; Franzolin, E.; Pontarin, G.; Ferraro, P.; Frangini, M.; Reichard, P.; Bianchi, V. Regulation by degradation, a cellular defense against deoxyribonucleotide pool imbalances. Mutat. Res. 2010, 703, 2–10. [Google Scholar] [CrossRef] [PubMed]
  28. Battelli, M.G.; Bolognesi, A.; Polito, L. Pathophysiology of circulating xanthine oxidoreductase: New emerging roles for a multi-tasking enzyme. Biochim. Biophys. Acta 2014, 1842, 1502–1517. [Google Scholar] [CrossRef] [PubMed]
  29. Steiger, S.; Harper, J.L. Mechanisms of spontaneous resolution of acute gouty inflammation. Curr. Rheumatol. Rep. 2014, 16, 392. [Google Scholar] [CrossRef] [PubMed]
  30. Wheeler, L.J.; Mathews, C.K. Nucleoside triphosphate pool asymmetry in mammalian mitochondria. J. Biol. Chem. 2011, 286, 16992–16996. [Google Scholar] [CrossRef]
  31. Saada, A. Mitochondrial deoxyribonucleotide pools in deoxyguanosine kinase deficiency. Mol. Genet. Metab. 2008, 95, 169–173. [Google Scholar] [CrossRef] [PubMed]
  32. Ferraro, P.; Nicolosi, L.; Bernardi, P.; Reichard, P.; Bianchi, V. Mitochondrial deoxynucleotide pool sizes in mouse liver and evidence for a transport mechanism for thymidine monophosphate. Proc. Natl. Acad. Sci. USA 2006, 103, 18586–18991. [Google Scholar] [CrossRef] [PubMed]
  33. Martí, R.; Dorado, B.; Hirano, M. Measurement of mitochondrial dNTP pools. Methods Mol. Biol. 2012, 837, 135–148. [Google Scholar] [PubMed]
  34. Jinnah, H.A.; Ceballos-Picot, I.; Torres, R.J.; Visser, J.E.; Schretlen, D.J.; Verdu, A.; Laróvere, L.E.; Chen, C.J.; Cossu, A.; Wu, C.H.; et al.; Lesch-Nyhan Disease International Study Group Attenuated variants of Lesch-Nyhan disease. Brain 2010, 133 Pt 3, 671–689. [Google Scholar] [CrossRef] [PubMed]
  35. Mizunuma, M.; Fujimori, S.; Ogino, H.; Ueno, T.; Inoue, H.; Kamatani, N. A recurrent large Alu-mediated deletion in the hypoxanthine phosphoribosyltransferase (HPRT1) gene associated with Lesch-Nyhan syndrome. Hum. Mutat. 2001, 18, 435–443. [Google Scholar] [CrossRef] [PubMed]
  36. Sampat, R.; Fu, R.; Larovere, L.E.; Torres, R.J.; Ceballos-Picot, I.; Fischbach, M.; de Kremer, R.; Schretlen, D.J.; Puig, J.G.; Jinnah, H.A. Mechanisms for phenotypic variation in Lesch-Nyhan disease and its variants. Hum. Genet. 2011, 129, 71–78. [Google Scholar] [CrossRef] [PubMed]
  37. Camici, M.; Micheli, V.; Ipata, P.L.; Tozzi, M.G. Pediatric neurological syndromes and inborn errors of purine metabolism. Neurochem. Int. 2010, 56, 367–378. [Google Scholar] [CrossRef] [PubMed]
  38. Ernst, M.; Zametkin, A.J.; Matochik, J.A.; Pascualvaca, D.; Jons, P.H.; Hardy, K.; Hankerson, J.G.; Doudet, D.J.; Cohen, R.M. Presynaptic dopaminergic deficits in Lesch-Nyhan disease. N. Engl. J. Med. 1996, 334, 1568–1572. [Google Scholar] [CrossRef] [PubMed]
  39. Wong, D.F.; Harris, J.C.; Naidu, S.; Yokoi, F.; Marenco, S.; Ravert, H.T.; Yaster, M.; Evans, A.; Rousset, O.; Bryan, R.N.; et al. Dopamine transporter are markedly reduced in Lesch-Nyhan disease in vivo. Proc. Natl. Acad. Sci. USA 1996, 93, 5539–5543. [Google Scholar] [CrossRef] [PubMed]
  40. White, W.F.; Dichter, M.A.; Snodgrass, R. Benzodiazepine binding and interactions with the GABA receptor complex in living cultures of rat cerebral cortex. Brain Res. 1981, 215, 162–176. [Google Scholar] [CrossRef] [PubMed]
  41. Göttle, M.; Prudente, C.N.; Fu, R.; Sutcliffe, D.; Pang, H.; Cooper, D.; Veledar, E.; Glass, J.D.; Gearing, M.; Visser, J.E.; et al. Loss of dopamine phenotype among midbrain neurons in Lesch-Nyhan disease. Ann. Neurol. 2014, 76, 95–107. [Google Scholar] [CrossRef] [PubMed]
  42. Fairbanks, L.D.; Jacomelli, G.; Micheli, V.; Slade, T.; Simmonds, H.A. Severe pyridine nucleotide depletion in fibroblasts from Lesch-Nyhan patients. J. Neurochem. 1999, 72, 1139–1145. [Google Scholar] [PubMed]
  43. McCreanor, G.M.; Harkness, R.A. Lesch-Nyhan syndrome and its pathogenesis: Normal nicotinamide-adenine dinucleotide but reduced ATP concentrations that correlate with reduced poly(ADP-ribose) synthetase activity in HPRT-deficient lymphoblasts. J. Inherit. Metab. Dis. 1995, 18, 737–747. [Google Scholar] [CrossRef] [PubMed]
  44. Kang, T.H.; Park, Y.; Bader, J.S.; Friedmann, T. The housekeeping gene hypoxanthine guanine phosphoribosyltransferase (HPRT) regulates multiple developmental and metabolic pathways of murine embryonic stem cell neuronal differentiation. PLoS ONE 2013, 8, e74967. [Google Scholar] [CrossRef] [PubMed]
  45. Mastrangelo, L.; Kim, J.E.; Miyanohara, A.; Kang, T.H.; Friedmann, T. Purinergic signaling in human pluripotent stem cells is regulated by the housekeeping gene encoding hypoxanthine guanine phosphoribosyltransferase. Proc. Natl. Acad. Sci. USA 2012, 109, 3377–3382. [Google Scholar] [CrossRef] [PubMed]
  46. Guibinga, G.H.; Murray, F.; Barron, N. HPRT-deficiency dysregulates cAMP-PKA signaling and phosphodiesterase 10A expression: Mechanistic insight and potential target for Lesch-Nyhan Disease? PLoS ONE 2013, 18, e63333. [Google Scholar] [CrossRef]
  47. Watts, R.W.; Harkness, R.A.; Spellacy, E.; Taylor, N.F. Lesch-Nyhan syndrome: Growth delay, testicular atrophy and a partial failure of the 11β-hydroxylation of steroids. J. Inherit. Metab. Dis. 1987, 10, 210–223. [Google Scholar] [CrossRef] [PubMed]
  48. Copeland, W.C. Defects in mitochondrial DNA replication and human disease. Crit. Rev. Biochem. Mol. Biol. 2012, 47, 64–74. [Google Scholar] [CrossRef]
  49. Tyynismaa, H.; Suomalainen, A. Mouse models of mitochondrial DNA defects and their relevance for human disease. EMBO Rep. 2009, 10, 137–143. [Google Scholar] [CrossRef] [PubMed]
  50. Mandel, H.; Szargel, R.; Labay, V.; Elpeleg, O.; Saada, A.; Shalata, A.; Anbinder, Y.; Berkowitz, D.; Hartman, C.; Barak, M.; et al. The deoxyguanosine kinase gene is mutated in individuals with depleted hepatocerebral mitochondrial DNA. Nat. Genet. 2001, 29, 337–341. [Google Scholar] [CrossRef] [PubMed]
  51. Johansson, M.; Karlsson, A. Cloning and expression of human deoxyguanosine kinase cDNA. Proc. Natl. Acad. Sci. USA 1996, 93, 7258–7262. [Google Scholar] [CrossRef] [PubMed]
  52. Eriksson, S.; Wang, L. Molecular mechanisms of mitochondrial DNA depletion diseases caused by deficiencies in enzymes in purine and pyrimidine metabolism. Nucleosides Nucleotides Nucleic Acids 2008, 27, 800–808. [Google Scholar] [CrossRef] [PubMed]
  53. Dimmock, D.P.; Zhang, Q.; Dionisi-Vici, C.; Carrozzo, R.; Shieh, J.; Tang, L.-Y.; Truong, C.; Schmitt, E.; Sifry-Platt, M.; Lucioli, S.; et al. Clinical and molecular features of mitochondrial DNA depletion due to mutations in deoxyguanosine kinase. Hum. Mutat. 2008, 29, 330–331. [Google Scholar] [CrossRef] [PubMed]
  54. Freisinger, P.; Fütterer, N.; Lankes, E.; Gempel, K.; Berger, T.M.; Spalinger, J.; Hoerbe, A.; Schwantes, C.; Lindner, M.; Santer, R.; et al. Hepatocerebral mitochondrial DNA depletion syndrome caused by deoxyguanosine kinase (DGUOK) mutations. Arch. Neurol. 2006, 63, 1129–1134. [Google Scholar] [CrossRef] [PubMed]
  55. Buchaklian, A.H.; Helbling, D.; Ware, S.M.; Dimmock, D.P. Recessive deoxyguanosine kinase deficiency causes juvenile onset mitochondrial myopathy. Mol. Genet. Metab. 2012, 107, 92–94. [Google Scholar] [CrossRef] [PubMed]
  56. Tyynismaa, H.; Sun, R.; Ahola-Erkkilä, S.; Almusa, H.; Pöyhönen, R.; Korpela, M.; Honkaniemi, J.; Isohanni, P.; Paetau, A.; Wang, L.; et al. Thymidine kinase 2 mutations in autosomal recessive progressive external ophthalmoplegia with multiple mitochondrial DNA deletions. Hum. Mol. Genet. 2012, 21, 66–75. [Google Scholar] [CrossRef] [PubMed]
  57. Kalko, S.G.; Paco, S.; Jou, C.; Rodríguez, M.A.; Meznaric, M.; Rogac, M.; Jekovec-Vrhovsek, M.; Sciacco, M.; Moggio, M.; Fagiolari, G.; et al. Transcriptomic profiling of TK2 deficient human skeletal muscle suggests a role for the p53 signalling pathway and identifies growth and differentiation factor-15 as a potential novel biomarker for mitochondrial myopathies. BMC Genomics 2014, 15, 91. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  58. Giordano, C.; Sebastiani, M.; de Giorgio, R.; Travaglini, C.; Tancredi, A.; Valentino, M.L.; Bellan, M.; Cossarizza, A.; Hirano, M.; d’Amati, G.; et al. Gastrointestinal dysmotility in mitochondrial neurogastrointestinal encephalomyopathy is caused by mitochondrial DNA depletion. Am. J. Pathol. 2008, 173, 1120–1128. [Google Scholar] [CrossRef]
  59. Libernini, L.; Lupis, C.; Mastrangelo, M.; Carrozzo, R.; Santorelli, F.M.; Inghilleri, M.; Leuzzi, V. Mitochondrial neurogastrointestinal encephalomyopathy: Novel pathogenic mutations in thymidine phosphorylase gene in two Italian brothers. Neuropediatrics 2012, 43, 201–208. [Google Scholar] [CrossRef] [PubMed]
  60. Valentino, M.L.; Martí, R.; Tadesse, S.; López, L.C.; Manes, J.L.; Lyzak, J.; Hahn, A.; Carelli, V.; Hirano, M. Thymidine and deoxyuridine accumulate in tissues of patients with mitochondrial neurogastrointestinal encephalomyopathy (MNGIE). FEBS. Lett. 2007, 581, 3410–3414. [Google Scholar] [CrossRef] [PubMed]
  61. González-Vioque, E.; Torres-Torronteras, J.; Andreu, A.L.; Martí, R. Limited dCTP availability accounts for mitochondrial DNA depletion in mitochondrial neurogastrointestinal encephalomyopathy (MNGIE). PLoS Genet. 2011, 7, e1002035. [Google Scholar] [CrossRef] [PubMed]
  62. Filosto, M.; Scarpelli, M.; Tonin, P.; Lucchini, G.; Pavan, F.; Santus, F.; Parini, R.; Donati, M.A.; Cotelli, M.S.; Vielmi, V.; et al. Course and management of allogeneic stem cell transplantation in patients with mitochondrial neurogastrointestinal encephalomyopathy. J. Neurol. 2012, 259, 2699–2706. [Google Scholar] [CrossRef] [PubMed]
  63. Tyynismaa, H.; Carroll, C.J.; Raimundo, N.; Ahola-Erkkilä, S.; Wenz, T.; Ruhanen, H.; Guse, K.; Hemminki, A.; Peltola-Mjøsund, K.E.; Tulkki, V.; et al. Mitochondrial myopathy induces a starvation-like response. Hum. Mol. Genet. 2010, 19, 3948–3958. [Google Scholar] [CrossRef] [PubMed]
  64. Bourdon, A.; Minai, L.; Serre, V.; Jais, J.P.; Sarzi, E.; Aubert, S.; Chrétien, D.; de Lonlay, P.; Paquis-Flucklinger, V.; Arakawa, H.; et al. Mutation of RRM2B, encoding p53-controlled ribonucleotide reductase (p53R2), causes severe mitochondrial DNA depletion. Nat. Genet. 2007, 39, 776–780. [Google Scholar] [CrossRef] [PubMed]
  65. Pontarin, G.; Ferraro, P.; Rampazzo, C.; Kollberg, G.; Holme, E.; Reichard, P.; Bianchi, V. Deoxyribonucleotide metabolism in cycling and resting human fibroblasts with a missense mutation in p53R2, a subunit of ribonucleotide reductase. J. Biol. Chem. 2011, 286, 11132–11140. [Google Scholar] [CrossRef] [PubMed]
  66. Tyynismaa, H.; Ylikallio, E.; Patel, M.; Molnar, M.J.; Haller, R.G.; Suomalainen, A. A heterozygous truncating mutation in RRM2B causes autosomal-dominant progressive external ophthalmoplegia with multiple mtDNA deletions. Am. J. Hum. Genet. 2009, 85, 290–295. [Google Scholar] [CrossRef] [PubMed]
  67. Eaton, J.S.; Lin, Z.P.; Sartorelli, A.C.; Bonawitz, N.D.; Shadel, G.S. Ataxia-telangiectasia mutated kinase regulates ribonucleotide reductase and mitochondrial homeostasis. J. Clin. Investig. 2007, 117, 2723–2734. [Google Scholar] [CrossRef] [PubMed]
  68. Hooper, M.; Hardy, K.; Handyside, A.; Hunter, S.; Monk, M. HPRT-deficient (Lesch-Nyhan) mouse embryos derived from germline colonization by cultured cells. Nature 1987, 326, 292–295. [Google Scholar] [CrossRef] [PubMed]
  69. Jinnah, H.A.; Page, T.; Friedmann, T. Brain purines in a genetic mouse model of Lesch-Nyhan disease. J. Neurochem. 1993, 60, 2036–2045. [Google Scholar] [CrossRef] [PubMed]
  70. Visser, J.E.; Smith, D.W.; Moy, S.S.; Breese, G.R.; Friedmann, T.; Rothstein, J.D.; Jinnah, H.A. Oxidative stress and dopamine deficiency in a genetic mouse model of Lesch-Nyhan disease. Brain Res. Dev. Brain Res. 2002, 133, 127–139. [Google Scholar] [CrossRef] [PubMed]
  71. Pelled, D.; Sperling, O.; Zoref-Shani, E. Abnormal purine and pyrimidine nucleotide content in primary astroglia cultures from hypoxanthine-guanine phosphoribosyltransferase-deficient transgenic mice. J. Neurochem. 1999, 72, 1139–1145. [Google Scholar] [CrossRef] [PubMed]
  72. Jinnah, H.A.; de Gregorio, L.; Harris, J.C.; Nyhan, W.L.; O’Neill, J.P. The spectrum of inherited mutations causing HPRT deficiency: 75 new cases and a review of 196 previously reported cases. Mutat. Res. 2000, 463, 309–326. [Google Scholar] [CrossRef] [PubMed]
  73. Zhou, X.; Solaroli, N.; Bjerke, M.; Stewart, J.B.; Rozell, B.; Johansson, M.; Karlsson, A. Progressive loss of mitochondrial DNA in thymidine kinase 2-deficient mice. Hum. Mol. Genet. 2008, 17, 2329–2335. [Google Scholar] [CrossRef] [PubMed]
  74. Akman, H.O.; Dorado, B.; López, L.C.; García-Cazorla, A.; Vilà, M.R.; Tanabe, L.M.; Dauer, W.T.; Bonilla, E.; Tanji, K.; Hirano, M. Thymidine kinase 2 (H126N) knockin mice show the essential role of balanced deoxynucleotide pools for mitochondrial DNA maintenance. Hum. Mol. Genet. 2008, 17, 2433–2440. [Google Scholar] [CrossRef] [PubMed]
  75. Krishnan, S.; Paredes, J.A.; Zhou, X.; Kuiper, R.V.; Curbo, S.; Karlsson, A. Long term expression of Drosophila melanogaster nucleoside kinase in thymidine kinase 2-deficient mice with no lethal effects caused by nucleotide pool imbalances. J. Biol. Chem. 2014, 288, 32835–32844. [Google Scholar] [CrossRef]
  76. Lopez, L.C.; Akman, H.O.; García-Cazorla, A.; Dorado, B.; Martí, R.; Nishino, I.; Tadesse, S.; Pizzorno, G.; Shungu, D.; Bonilla, E.; et al. Unbalanced deoxynucleotide pools cause mitochondrial DNA instability in thymidine phosphorylase-deficient mice. Hum. Mol. Genet. 2009, 18, 714–722. [Google Scholar] [CrossRef] [PubMed]
  77. Kimura, T.; Takeda, S.; Sagiya, Y.; Gotoh, M.; Nakamura, Y.; Arakawa, H. Impaired function of p53R2 in Rrm2b-null mice causes severe renal failure through attenuation of dNTP pools. Nat. Genet. 2003, 34, 440–445. [Google Scholar] [CrossRef] [PubMed]
  78. Ylikallio, E.; Page, J.L.; Xu, X.; Lampinen, M.; Bepler, G.; Ide, T.; Tyynismaa, H.; Weiss, R.S.; Suomalainen, A. Ribonucleotide reductase is not limiting for mitochondrial DNA copy number in mice. Nucleic Acids Res. 2010, 38, 8208–8218. [Google Scholar] [CrossRef] [PubMed]
  79. Stern, N.; Hochman, A.; Zemach, N.; Weizman, N.; Hammel, I.; Shiloh, Y.; Rotman, G.; Barzilai, A. Accumulation of DNA damage and reduced levels of nicotine adenine dinucleotide in the brains of Atm-deficient mice. J. Biol. Chem. 2002, 277, 602–608. [Google Scholar] [CrossRef] [PubMed]
  80. Lavin, M.F. The appropriateness of the mouse model for ataxia-telangiectasia: Neurological defects but no neurodegeneration. DNA Repair 2013, 12, 612–619. [Google Scholar] [CrossRef] [PubMed]
  81. Fasullo, M.; Tsaponina, O.; Sun, M.; Chabes, A. Elevated dNTP levels suppress hyper-recombination in Saccharomyces cerevisiae S-phase checkpoint mutants. Nucleic Acids Res. 2010, 38, 1195–1203. [Google Scholar] [CrossRef] [PubMed]
  82. Taylor, S.D.; Zhang, H.; Eaton, J.S.; Rodeheffer, M.S.; Lebedeva, M.A.; O’Rourke, T.W.; Siede, W.; Shadel, G.S. The conserved Mec1/Rad53 nuclear checkpoint pathway regulates mitochondrial DNA copy number in Saccharomyces cerevisiae. Mol. Biol. Cell 2005, 16, 3010–3018. [Google Scholar] [CrossRef] [PubMed]
  83. Glick, N. Dramatic reduction in self-injury in Lesch-Nyhan disease following S-adenosylmethionine administration. J. Inherit. Metab. Dis. 2006, 29, 687. [Google Scholar] [CrossRef] [PubMed]
  84. El-Hattab, A.E.; Scaglia, F. Mitochondrial DNA depletion syndromes: Review and updates of genetic basis, manifestations, and therapeutic options. Neurotherapeutics 2013, 10, 186–198. [Google Scholar] [CrossRef] [PubMed]

Share and Cite

MDPI and ACS Style

Fasullo, M.; Endres, L. Nucleotide Salvage Deficiencies, DNA Damage and Neurodegeneration. Int. J. Mol. Sci. 2015, 16, 9431-9449. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms16059431

AMA Style

Fasullo M, Endres L. Nucleotide Salvage Deficiencies, DNA Damage and Neurodegeneration. International Journal of Molecular Sciences. 2015; 16(5):9431-9449. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms16059431

Chicago/Turabian Style

Fasullo, Michael, and Lauren Endres. 2015. "Nucleotide Salvage Deficiencies, DNA Damage and Neurodegeneration" International Journal of Molecular Sciences 16, no. 5: 9431-9449. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms16059431

Article Metrics

Back to TopTop