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The role of frataxin in mitochondrial iron and haem metabolism and the development of iron chelators as potential therapeutic agents for the treatment of Friedreich's ataxia /Becker, Erika Michelle. January 2002 (has links) (PDF)
Thesis (Ph. D.)--University of Queensland, 2003. / Includes bibliographical references.
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Genetic and molecular investigation of the spinocerebellar ataxiasHayes, Sean I. A. January 1999 (has links)
The spinocerebellar ataxias (SCAs) are a clinically and genetically heterogeneous group of neurodegenerative disorders. To date, ten SCA loci have been described (SCA1-SCA8, SCA10 and SCA11), with six genes having been cloned (SCA1, SCA2, SCA3/MJD, SCA6, SCA7 and SCA8) and shown to contain CAG/CTG repeats. / This study investigated various aspects of the SCA2, SCA6, and SCA7 subtypes. Haplotype analysis in our panel of SCA2 families identified multiple ancestral mutation events to be responsible for disease in this group. Screening for the newly identified SCA6 and SCA7 mutations in our large collection of SCA families and patients revealed that these mutations are rare in our panel, each accounting for less than 1% of our ataxia samples. Finally, the CAG repeat-containing locus hGT1 was found to be associated with residual age at onset variability in our SCA2 families. / Together, these results add to our growing understanding of the SCAs, and bring us a few steps closer to effective diagnoses of, and treatments for, these devastating diseases.
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Genetic and molecular investigation of the spinocerebellar ataxiasHayes, Sean I. A. January 1999 (has links)
No description available.
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Molecular genetics of autosomal recessive spinocerebellar ataxiasChristodoulou, Kyproula January 1995 (has links)
No description available.
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Frataxin (FXN) Based Regulation of the Iron-Sulfur Cluster Assembly ComplexRabb, Jennifer 2012 May 1900 (has links)
Iron-sulfur clusters are protein cofactors that are critical for all life forms. Elaborate multi-component systems have evolved for the biosynthesis of these cofactors to protect organisms from the toxic effects of free iron and sulfide ions. In eukaryotes, the Fe-S cluster assembly machinery operates in the matrix space of the mitochondria and contains a myriad of proteins that mediate sulfur, iron, and electron transfer to assemble Fe-S clusters on the scaffold protein ISCU2 and then distribute these clusters to target proteins. Our lab has recently described stable 3, and 4-protein complexes composed of the cysteine desulfurase NFS1, the co-chaperone ISD11, and ISCU2 (SDU), and NFS1, ISD11, ISCU2, and FXN (SDUF) subunits. In the latter, SDUF, FXN functions as an allosteric activator switching this assembly complex on for Fe-S cluster biosynthesis. Insufficient expression of the mitochondrial protein FXN leads to a progressive neurodegenerative disease, Friedreich's Ataxia (FRDA). In ~2% of patients, FRDA is caused by one of 15 known missense mutations on one allele accompanied by the GAA repeat on the other leading to a complicated phenotype that includes loss of Fe-S clusters. Here we present in vitro evidence that FRDA FXN variants are deficient in their ability to bind the SDU complex, their ability to stimulate the sulfur transfer reaction from NFS1 to ISCU2, and in their ability to stimulate the rate of cluster assembly on ISCU2. Here, in vitro evidence is presented that FXN accelerates the sulfur transfer reaction from NFS1 to ISCU2. Additionally, we present kinetic evidence that identifies the most buried cysteine residue, C104 on ISCU2 as the sulfur acceptor residue suggesting, FXN stabilizes a conformational change to facilitate sulfur delivery. Subsequent mutational studies suggest FXN binding to SDU results in a helix to coil transition in ISCU2 exposing C104 to accept the persulfide sulfur and thereby accelerating the rate of sulfur transfer. We further provide the first biochemical evidence that the persulfide transferred to ISCU2 from NFS1 is viable in Fe-S cluster formation. In contrast to human FXN, the Escherichia coli FXN homolog CyaY has been reported to inhibit Fe-S cluster biosynthesis. To resolve this discrepancy, a series of inter-species enzyme kinetic experiments were performed. Surprisingly, our results reveal that activation or inhibition by the frataxin homolog is determined by which cysteine desulfurase is present and not by the identity of the frataxin homolog. These data are consistent with a model in which the frataxin-less Fe-S assembly complex exists as a mixture of functional and nonfunctional states, which are stabilized by binding of frataxin homologs. Intriguingly, this appears to be an unusual example in which modifications to an enzyme during evolution inverts or reverses the mode of control imparted by a regulatory molecule.
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Genetic and clinical profile of the spinocerebellar ataxias followed in the Calgary Movement Disorders Clinic /Kraft, Scott W., January 2003 (has links)
Thesis (M.Sc.)--Memorial University of Newfoundland, 2004. / Bibliography: leaves 79-97.
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The function of yeast frataxin in iron-sulfur cluster biogenesis : a systematic mutagenesis of solvent-exposed side chains of the beta-sheet platformLeidgens, Sébastien 26 September 2008 (has links)
Friedreich's ataxia is a neurodegenerative disorder caused by the low expression of a mitochondrial protein called frataxin. Studies in the yeast Saccharomyces cerevisiae have unraveled a role for the frataxin homologue (Yfh1p) in iron-sulfur cluster (Fe/S) biosynthesis, probably by interacting with the scaffold protein, Isu1p, and providing iron to the machinery. Yfh1p possesses a large â-sheet platform that may be involved in the interaction with other proteins through conserved residues at its surface. We have used directed mutagenesis associated with polymerase chain reaction (PCR) to study conserved residues localizing either at the surface of the protein, Thr110, Thr118, Val120, Asn122, Gln124, Gln129, Trp131, Ser137 and Arg141, or buried in the core of the protein, Ile130 and Leu132.
Mutants T110A, T118A, V120A, N122A, Q124A, Q129A, I130A, W131A, L132A, S137A and R141A were generated in yeast. Growth on iron- or copper-containing medium was severely impaired for mutants Q129A, I130A, W131A and R141A. Others were roughly growing as well as the wild-type strain. We assessed the efficiency of Fe/S biosynthesis by measuring aconitase activity. The results confirmed those obtained on metal-containing medium: mutants Q129A, I130A, W131A and R141A showed a high decrease in their aconitase activity that dropped to the deleted strain level. Moreover, S137A showed also a decreased aconitase activity. We monitored the interaction between Yfh1p and Isu1p by co-immunoprecipitation and it turned out that only the W131A mutation affects directly this interaction. Even if the amount of Yfh1p determined by western blot analysis was highly decreased for several mutants, it is not sufficient to explain the phenotypes as they were poorly restored by overexpression of the mutant proteins to wild-type levels, except for W131F.
We have concluded that Gln129, Trp131, and Arg141 are important for Yfh1p function, while Ile130 and Ser137 are required for the folding of the protein. All these residues cluster to the 4th and 5th â-strand of the protein. Our work has demonstrated for the first time the importance of this area for Yfh1p function and shows that Trp131 is involved in the interaction with Isu1p.
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Overcoming frataxin gene silencing in Friedreich’s ataxia with small molecules: studies on cellular and animal modelsRai, Myriam 05 January 2010 (has links)
Friedreich’s ataxia (FRDA) is an inherited recessive disorder characterized by progressive neurological disability and heart disease. It is caused by a pathological intronic hyperexpansion of a GAA repeat in the FXN gene, encoding the essential mitochondrial protein frataxin. At the homozygous state, the GAA expansion induces a heterochromatin state with decreased histone acetylation and increased methylation, resulting in a partial deficiency of frataxin expression. This was established in cells from FRDA patients. We showed that the same chromatin changes exist in a GAA based mouse model, KIKI, generated in our laboratory. Furthermore, treatment of KIKI mice with a novel Histone Deacetylase Inhibitor (HDACi), 106, a pimelic diphenylamide that increases frataxin levels in FRDA cell culture, restored frataxin levels in the nervous system and heart of KIKI mice and induced histone hyperacetylation near the GAA repeat. As shown by microarrays, most of the differentially expressed genes in KIKI were corrected towards wild type. In an effort to improve the pharmacological profile of compound 106, we synthesized more compounds based on its structure and specificity. We characterized two of these compounds in FRDA patients’ peripheral blood lymphocytes and in the KIKI mouse model. We observed a sustained frataxin upregulation in both systems, and, by following the time course of the events, we concluded that the effects of these compounds last longer than the time of direct exposure to HDACi. Our results support the pre-clinical development of a therapeutic approach based on pimelic diphenylamide HDACis for FRDA. Laboratory tools to follow disease progression and assess drug efficacy are needed in a slowly progressive neurodegenerative disease such as FRDA. We used microarrays to characterize the gene expression profile in peripheral lymphocytes from FRDA patients, carriers and controls. We identified gene expression changes in heterozygous, clinically unaffected GAA expansion carriers, suggesting that they present a biochemical phenotype, consistent with data from animal models of frataxin deficiency. We identified a subset of genes changing in patients as a result of pathological frataxin deficiency establishing robust gene expression changes in peripheral lymphocytes. These changes can be used as a biomarker to monitor disease progression and potentially assess drug efficacy. To this end, we used he same methodology to characterize the gene expression profiles in peripheral lymphocytes after treatment with pimelic diphenylamide HDACi. This treatment had relevant effects on gene expression on peripheral patients’ blood lymphocytes. It increased frataxin levels in a dose-dependent manner, and partially rescued the gene expression phenotype associated with frataxin deficiency in the tested cell model, thus providing the first application of a biomarker gene set in FRDA.
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Novel Diagnostic Approaches for Genetic and Environmental Sources of Mitochondrial DysfunctionThomson, Alexander Hugh 14 June 2023 (has links)
With cardiovascular disease, diabetes mellitus, and neurodegenerative conditions on the rise, understanding their pathogenesis is paramount to tackling this public health crisis. Current research indicates that the primary cause of these diseases is mitochondrial dysfunction in the affected patients. While genetics plays a role in these conditions, lifestyle choices and exposure to toxins also significantly contribute to their development. Unfortunately, early-stage diagnosis can be difficult due to overlapping symptoms with other diseases. Developing innovative therapies that can prevent or reverse the deterioration of metabolic dysfunctions is critical to establishing early intervention. My research focused on investigating molecular targets linked with Friedrich's Ataxia, an inherited metabolic disorder, through conducting functional in-vitro studies using human-derived cell samples, as well as developing inventive animal models created via Xenopus laevis tadpoles to evaluate the effects of environmental stressors. My investigations have uncovered promising treatment options that improve mitochondrial function, mitigate oxidative stress, and elucidate critical mechanisms involved in environmentally induced disruptions to mitochondria. / Doctor of Philosophy / Metabolic dysfunction is a widespread health issue that affects millions of individuals each day. Its associated disorders, such as cardiovascular disease, diabetes, and neurodegenerative conditions, are rising due to various factors ranging from genetic predispositions to environmental and lifestyle-related risks. Therefore, there's an urgent need to identify this disorder early on and develop innovative treatment options. Considering this growing public health concern, it has become imperative to establish new methods for detecting metabolic dysfunction at its nascent stage while also exploring potential therapeutic interventions. Our research utilized cells derived from affected patients and animal models in devising novel approaches toward understanding the molecular mechanisms underpinning metabolic dysfunction. Our findings revealed several pathways and molecular targets contributing significantly to this condition, which could effectively be leveraged to develop targeted therapeutic strategies to combat its effects. Expanding our knowledge base will enable us to stay updated with emerging insights on treating metabolic dysfunction effectively while substantially improving patient outcomes.
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Priming Motor Learning through Exercise in People with Spinocerebellar Ataxia (PRIME-Ataxia)Macpherson, Chelsea Erin January 2024 (has links)
Background. People with spinocerebellar ataxia (SCA) have symptoms that impact balance, gait, motor learning and control. Independently, balance training (BT) and aerobic exercise (AE) have improved motor function for people with SCA. Studies in stroke and Parkinson disease have evaluated the use of AE prior to BT as a form of motor priming to enhance motor learning. Motor priming has not been explored in SCA.
Introduction & Purpose. This was a pilot randomized controlled trial aimed to 1) determine the feasibility and efficacy of an 8-week telehealth intervention of high intensity AE prior to BT (HIBT) compared to low intensity exercise prior to BT (LIBT) on disease specific motor and cognitive outcomes, and 2) explore changes in patient reported outcomes as well as functional outcomes post exercise intervention in people with SCA.
Methods. Participants (n=20) were randomized to receive either HIBT, or LIBT, for 60 minutes, twice weekly, for 8-weeks over telehealth. The HIBT group underwent 30 minutes of High Intensity Interval Training (HIIT) prior to 30 minutes of BT, while the LIBT group underwent 30 minutes of low intensity warm up type exercises prior to 30 minutes of BT. Outcomes were assessed at baseline, mid- and post-intervention and included: disease specific measures (e.g., Cerebellar Cognitive Affective Scale (CCAS), Scale for Assessment and Rating of Ataxia at Home (SARAHome), functional measures of balance and gait (e.g., Timed Up and Go test (TUG), 30 second Sit to Stand Test (30secSTS)), patient reported measures (e.g., fatigue severity scale (FSS-49)) and metrics of feasibility. Data for disease specific, and functional outcomes were not normally distributed. Data for patient reported outcomes was normally distributed. Statistical significance of findings are reported as p-value.
Results. A total of 93 people were referred to this intervention, and 20 were enrolled (21.5% enrollment). Eighteen participants completed the intervention and post-intervention outcome assessments (90% retention). Both the HIBT and LIBT interventions had high acceptance from on the post-intervention questionnaire. Enrolled participants had a mean (SD) age of 58.1(13.5) yrs; 6M/14F. Diagnoses were early-mid stage SCA types 1, 2, 3, and 6. Participants showed 100% adherence to the intervention, with 1 adverse event of low back pain exacerbation which resolved. Both groups improved on disease specific measures of the CCAS, and SARAHome where outcomes for the SARAHome surpassed the established group minimal detectable change score of 0.3 points. At post-intervention however, there were no between group differences identified on the SARAHome (p > .05), however for the CCAS the LIBT group demonstrated significant improvements at post intervention over the HIBT group (p < .01). There were no differences observed at post-intervention between groups for functional measures such as the TUG test, 30secSTS test, or in any static stance position. The LIBT group showed greater changes in fatigue post-intervention, (p < .05). The HIBT group showed no significant change in fatigue, however they displayed decreased tolerability to engage in BT after engagement in AE. The HIBT group managing to complete an average of only 8.50 BT exercises per session while LIBT completed 10.04.
Conclusions. Results from this pilot randomized controlled trial support a telehealth-delivered exercise intervention for people with SCA 1, 2, 3, and 6, with low overall attrition, and high rates of intervention adherence, and acceptability. However, effect estimates do not support the hypothesis of motor priming in people with SCA. Fatigue after engagement in AE limited intervention tolerability for BT in the HIBT group, and this suggests that fatigue may stand as a potential barrier for not only exercise engagement and functional improvement, but also neuroplastic growth and motor learning potential. Future research should aim to optimize exercise prescription to mitigate fatigue in this population.
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