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Elucidating the mechanism of prickle associated epilepsy in fliesEhaideb, Salleh Nasser 01 May 2015 (has links)
About 5% to 10% of epileptic patients suffer from Juvenile Myoclonic Epilepsy (JME), which is characterized by spasms of the arms, ataxia (uncoordinated movements), and general tonic-clonic seizures. In a recent study, a group of patients with myoclonic epilepsy was found to harbor mutations in the PRICKLE1 and PRICKLE2 genes. This suggested that PRICKLE genes might be linked to epilepsy, and given that PRICKLE is highly evolutionarily conserved (including in fruit flies), we decided to use Drosophila in order to determine, first, whether flies with prickle mutations were seizure-prone, and if so, to then use the powerful genetic tools of Drosophila to elucidate the underlying mechanism of the prickle-associated epilepsy. In this work, we show that mutation of the pksple isoform (one of the two adult prickle isoforms in flies) lowers the seizure threshold in the mutant flies (resulting in seizure activity), while mutation of the other adult isoform, pkpk, had no effect. This was demonstrated through both behavioral assays (where the pksple mutant flies showed a reduction in recovery of climbing behavior after being subjected to mechanical stimulation while the pkpk mutant flies did not) as well as electrophysiological analysis (where pksple mutants were shown to be hyperexcitable after electrical stimulation, while the pkpk allele showed no change in spiking activity). We demonstrated that the underlying mechanism of the hyperexcitability seen in the pksple flies was due to enhanced anterograde transport on microtubule (MT) tracks in neurons, the main route for transport in neurons, which could be suppressed by reducing the dose of either of two Kinesin motor proteins, the motors involved in anterograde transport in neurons. On the other hand, the pkpk mutants showed the reverse effect, exhibiting a significant reduction in vesicle transport dynamics. We showed that microtubule polarity could be partially reversed by tipping the balance of the pk isoforms similar to what is seen in the pkpk mutants (such that a large percentage of MTs now had their plus ends oriented towards the cell body, which is extremely rare in axons), suggesting that the vesicle transport defects seen in the pkpk mutants might be due to mixed polarity of MTs.
Next, we showed that the seizure-prone pksple mutants, but not the pkpk mutants, exhibited a myoclonic form of epilepsy, as well as abnormal walking patterns and uncoordinated movements, paralleling the ataxia phenotype seen in the epileptic patients with PRICKLE mutations. These data suggest that the primary aspects of the epilepsy-ataxia syndrome seen in patients with PRICKLE mutations are recapitulated in flies, which underscores the utility of using the fruit fly genetic system to model this disorder. Finally, our preliminary results suggest that the pk alleles have different effects on neuronal morphology due to changes in sizes of terminal boutons at the neuromuscular junction (NMJ) in larvae. These data suggest that pk is having a direct effect on synaptic formation and likely function.
In conclusion, by using our Drosophila model system, we were able to link prickle mutations to epilepsy as well as identify the cellular mechanism of the prickle-associated epilepsy, a novel epilepsy mechanism previously associated with neurodegeneration. To our knowledge, this is the first example of a gene that, when mutated, will cause seizures in flies, zebrafish, mice, and humans, indicating that the role of prickle in controlling seizure activity is remarkably conserved in animals. Significantly, since about one third of patients with epilepsy do not respond to current AEDs, our fly model and the techniques we have developed will enable us to conduct drug screens for testing potential chemical compounds as new AEDs.
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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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Cis-elements Affecting Disease-associated Repeat SequencesHagerman, Katharine Anne 03 March 2010 (has links)
The expansion of repetitive sequences leads to more than 40 neurological, neurodegenerative and neuromuscular diseases. These diseases are frequently characterized by ongoing DNA repeat instability upon transmission, worsening of disease severity and decreasing age of onset with each successive generation. The mechanism of repeat instability and contribution of repeat instability to disease pathogenesis are unknown. My thesis examines the contribution of cis-elements – sequences around and within repeats as well as surrounding epigenetic environments – to repeat instability, and discusses their possible contribution to repeat diseases.
Here I identify the first cis-element regulating repeat instability, a DNA binding site for a trans factor protein, CTCF. Loss of CTCF binding at the spinocerebellar ataxia type 7 disease locus induces somatic and germline instability in an age- and tissue-specific manner in mice. CTCF protects against instability in an epigenetic manner, and may function at other disease loci also possessing CTCF binding sites near the repeat.
Given that CTCF flanks many repeat loci and is often situated between a replication origin and disease-associated repeat, I assess the role of CTCF on replication and instability at the myotonic dystrophy repeat locus. Templates with CTCF binding sites reduce overall replication efficiency in primate cells that may be partly due to replication fork stalling. Mutating CTCF binding sites can alter the stability of the repeat depending on the distance from the origin of replication to the repeat.
Finally I examine chromatinization of (ATTCT)n repeats from the spinocerebellar ataxia type 10 locus. These repeats induce very strong nucleosome formation, and at physiological conditions form even more strongly on (ATTCT)n repeats with interruptions that are also found in some patients.
These data contribute to the understanding of repeat instability in the causation of many diseases, and suggest that the presence of cis-elements at repeat-associated disease loci alter the behaviour of repeats.
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Spatial deficits in visuomotor control following right parietal injuryBroderick, Carol Elizabeth January 2007 (has links)
Superior parietal cortex has been implicated in visuomotor guidance and is proposed to be specialised for action in the lower visual field and peripersonal space. Two patients, one with a right superior parietal lesion leading to optic ataxia (ME), and one with a lesion affecting right inferior parietal cortex (LH), were compared to elderly controls (n=8) and young controls (n=8) on a reciprocal pointing task with movements made in the near-far direction (i.e., sagittal plane) or right-left direction (i.e., fronto-parallel plane). In contrast to both control groups, who demonstrated a speed-accuracy trade-off in movement time and peak velocity, neither of the patients did. When the time spent post-peak velocity (represented as a percentage of total movement time) was examined, both patients demonstrated larger times post-peak velocity than controls for all movement directions. Furthermore, while rightward movements of the right hand had higher times post-peak velocity than leftward movements there were no directional patterns for near-far movements which contrasted with controls who had larger times post-peak velocity for near movements. The patient with the more superior lesion (ME) had the greatest difficulty with movements made back toward the body suggestive of a role for superior parietal cortex in the fine tuning of movements made in this region of space (i.e., personal or peripersonal space). In contrast, all directions of movement seemed to be equally affected in the patient with a more inferior lesion. These results are discussed in terms of the different roles played by inferior and superior parietal cortex in the control of visually guided movements.
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Cis-elements Affecting Disease-associated Repeat SequencesHagerman, Katharine Anne 03 March 2010 (has links)
The expansion of repetitive sequences leads to more than 40 neurological, neurodegenerative and neuromuscular diseases. These diseases are frequently characterized by ongoing DNA repeat instability upon transmission, worsening of disease severity and decreasing age of onset with each successive generation. The mechanism of repeat instability and contribution of repeat instability to disease pathogenesis are unknown. My thesis examines the contribution of cis-elements – sequences around and within repeats as well as surrounding epigenetic environments – to repeat instability, and discusses their possible contribution to repeat diseases.
Here I identify the first cis-element regulating repeat instability, a DNA binding site for a trans factor protein, CTCF. Loss of CTCF binding at the spinocerebellar ataxia type 7 disease locus induces somatic and germline instability in an age- and tissue-specific manner in mice. CTCF protects against instability in an epigenetic manner, and may function at other disease loci also possessing CTCF binding sites near the repeat.
Given that CTCF flanks many repeat loci and is often situated between a replication origin and disease-associated repeat, I assess the role of CTCF on replication and instability at the myotonic dystrophy repeat locus. Templates with CTCF binding sites reduce overall replication efficiency in primate cells that may be partly due to replication fork stalling. Mutating CTCF binding sites can alter the stability of the repeat depending on the distance from the origin of replication to the repeat.
Finally I examine chromatinization of (ATTCT)n repeats from the spinocerebellar ataxia type 10 locus. These repeats induce very strong nucleosome formation, and at physiological conditions form even more strongly on (ATTCT)n repeats with interruptions that are also found in some patients.
These data contribute to the understanding of repeat instability in the causation of many diseases, and suggest that the presence of cis-elements at repeat-associated disease loci alter the behaviour of repeats.
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Spatial deficits in visuomotor control following right parietal injuryBroderick, Carol Elizabeth January 2007 (has links)
Superior parietal cortex has been implicated in visuomotor guidance and is proposed to be specialised for action in the lower visual field and peripersonal space. Two patients, one with a right superior parietal lesion leading to optic ataxia (ME), and one with a lesion affecting right inferior parietal cortex (LH), were compared to elderly controls (n=8) and young controls (n=8) on a reciprocal pointing task with movements made in the near-far direction (i.e., sagittal plane) or right-left direction (i.e., fronto-parallel plane). In contrast to both control groups, who demonstrated a speed-accuracy trade-off in movement time and peak velocity, neither of the patients did. When the time spent post-peak velocity (represented as a percentage of total movement time) was examined, both patients demonstrated larger times post-peak velocity than controls for all movement directions. Furthermore, while rightward movements of the right hand had higher times post-peak velocity than leftward movements there were no directional patterns for near-far movements which contrasted with controls who had larger times post-peak velocity for near movements. The patient with the more superior lesion (ME) had the greatest difficulty with movements made back toward the body suggestive of a role for superior parietal cortex in the fine tuning of movements made in this region of space (i.e., personal or peripersonal space). In contrast, all directions of movement seemed to be equally affected in the patient with a more inferior lesion. These results are discussed in terms of the different roles played by inferior and superior parietal cortex in the control of visually guided movements.
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ATTENTION AND THE PARIETAL CORTEX: INVESTIGATIONS OF SPATIAL NEGLECT, OPTIC ATAXIA, AND THE INFLUENCE OF PRISM ADAPTATION ON ATTENTIONStriemer, Christopher 21 April 2008 (has links)
Some authors have argued that the primary function of the posterior parietal cortex is to control visual attention and awareness, whereas others have argued that the posterior parietal cortex is specialized for controlling actions. The purpose of the present thesis was to examine the influence of prism adaptation – a visuomotor adaptation technique – on visual attention deficits in patients with lesions of parietal cortex. Lesions to dorsal regions of the posterior parietal cortex lead to optic ataxia – a disorder in which visually guided reaching is disrupted. In contrast lesions to ventral (i.e. inferior) regions of the posterior parietal cortex of the right hemisphere lead to spatial neglect – a disorder in which patients are unaware of people or objects in contralesional (left) space. Chapter 1 presents an overview of the organization of the posterior parietal cortex, as well as an introduction to the disorders of spatial neglect and optic ataxia and the use of prism adaptation as a treatment for spatial neglect. Chapter 2 examined the influence of prism adaptation on attentional deficits in patients with right brain damage. Results demonstrated that prism adaptation reduced both the disengage deficit and the rightward attentional bias, two of the classic attentional deficits in neglect. Chapter 3 investigated the role of the dorsal posterior parietal cortex in controlling both reflexive and voluntary attention in two patients with optic ataxia. Lesions to the dorsal posterior parietal cortex led to both a disengage deficit and a rightward attentional bias, similar to patients with neglect, even though neither of the patients had any clinical symptoms of neglect. Contrary to previous work these results indicated that dorsal portions of the posterior parietal cortex – a region not commonly damaged in neglect – are important for controlling the orienting and reorienting of both reflexive and voluntary attention. Furthermore, these results indicated that optic ataxia is not purely a visuomotor disorder that is independent of any perceptual or attentional deficits as was previously assumed. Based on the results of Chapters 2 and 3 it was hypothesized that the beneficial effects of prism adaptation on attention may operate via the superior parietal lobe, a region which is typically undamaged in neglect, and is known to be important for controlling attention and action. Chapter 4 provided support for this hypothesis by demonstrating that a patient with lesions to the superior parietal lobe, who had the same attentional deficits as the right brain damaged patients tested in Chapter 2, failed to demonstrate any beneficial effects of prism adaptation on his attentional performance. Specifically, prism adaptation had no influence on his disengage deficit or his rightward attentional bias. Therefore, these data provide direct evidence that the beneficial effects of prisms on attention rely, at least in part, on the superior parietal lobe. Finally, Chapter 5 concludes with a summary of the research findings from the present thesis, and puts forward a new theory to conceptualize the mechanisms underlying the beneficial effects of prisms in patients with neglect.
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ATTENTION AND THE PARIETAL CORTEX: INVESTIGATIONS OF SPATIAL NEGLECT, OPTIC ATAXIA, AND THE INFLUENCE OF PRISM ADAPTATION ON ATTENTIONStriemer, Christopher 21 April 2008 (has links)
Some authors have argued that the primary function of the posterior parietal cortex is to control visual attention and awareness, whereas others have argued that the posterior parietal cortex is specialized for controlling actions. The purpose of the present thesis was to examine the influence of prism adaptation – a visuomotor adaptation technique – on visual attention deficits in patients with lesions of parietal cortex. Lesions to dorsal regions of the posterior parietal cortex lead to optic ataxia – a disorder in which visually guided reaching is disrupted. In contrast lesions to ventral (i.e. inferior) regions of the posterior parietal cortex of the right hemisphere lead to spatial neglect – a disorder in which patients are unaware of people or objects in contralesional (left) space. Chapter 1 presents an overview of the organization of the posterior parietal cortex, as well as an introduction to the disorders of spatial neglect and optic ataxia and the use of prism adaptation as a treatment for spatial neglect. Chapter 2 examined the influence of prism adaptation on attentional deficits in patients with right brain damage. Results demonstrated that prism adaptation reduced both the disengage deficit and the rightward attentional bias, two of the classic attentional deficits in neglect. Chapter 3 investigated the role of the dorsal posterior parietal cortex in controlling both reflexive and voluntary attention in two patients with optic ataxia. Lesions to the dorsal posterior parietal cortex led to both a disengage deficit and a rightward attentional bias, similar to patients with neglect, even though neither of the patients had any clinical symptoms of neglect. Contrary to previous work these results indicated that dorsal portions of the posterior parietal cortex – a region not commonly damaged in neglect – are important for controlling the orienting and reorienting of both reflexive and voluntary attention. Furthermore, these results indicated that optic ataxia is not purely a visuomotor disorder that is independent of any perceptual or attentional deficits as was previously assumed. Based on the results of Chapters 2 and 3 it was hypothesized that the beneficial effects of prism adaptation on attention may operate via the superior parietal lobe, a region which is typically undamaged in neglect, and is known to be important for controlling attention and action. Chapter 4 provided support for this hypothesis by demonstrating that a patient with lesions to the superior parietal lobe, who had the same attentional deficits as the right brain damaged patients tested in Chapter 2, failed to demonstrate any beneficial effects of prism adaptation on his attentional performance. Specifically, prism adaptation had no influence on his disengage deficit or his rightward attentional bias. Therefore, these data provide direct evidence that the beneficial effects of prisms on attention rely, at least in part, on the superior parietal lobe. Finally, Chapter 5 concludes with a summary of the research findings from the present thesis, and puts forward a new theory to conceptualize the mechanisms underlying the beneficial effects of prisms in patients with neglect.
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Abnormal reproductive function in female homozygous leaner miceSerpedin, Nesrin 30 September 2004 (has links)
The leaner mouse carries an autosomal recessive mutation in the α1A subunit of neuronal P/Q-type voltage gated calcium ion channels. Due to this mutation, the leaner mouse exhibits severe ataxia, absence seizures and paroxysmal dyskinesia. Mutations in this same gene in humans cause: episodic ataxia type 2, familial hemiplegic migraine, spinocerebellar ataxia type 6 and probably the newly recognized form of human inherited epilepsy.
Decreased amplitude of calcium current in cerebellar Purkinje cells and decreased calcium buffering capacity suggest that failure of calcium homeostasis may lead to the neurodegeneration observed in these mutant mice. Both sexes are affected. Despite their neurological dysfunction, homozygous leaner mice are able to breed and produce viable offspring. The survival rate for these pups is highly correlated with early fostering to normal lactating dams.
This thesis studies the reproductive dysfunction observed in female homozygous leaner mice and is divided into four parts: onset of puberty, estrous cycle, pregnancy and litter assessment, and hormone levels. We have discovered that the onset of puberty is precocious in leaner females compared to age-matched wild type females, and leaner mice spend more time in estrous than age-matched wild type females. Also, we have observed that leaner mice became pregnant less readily than wild type mice, but once pregnant, female leaner mice produced more pups per litter compared with wild type mice. The number of corpora lutea observed in leaner mice is greater than in wild type mice. In leaner mice, the number of corpora lutea in the ovary corresponding to the uterine horn with the highest number of offspring is larger than the number of corpora lutea found in the ovary corresponding to the other uterine horn. Radioimmunoassays of estradiol hormone levels at postnatal day 28 shows higher levels in leaner compared to age-matched wild type mice. However, at postnatal day 28, the luteinizing hormone levels are similar in both categories of mice.
This study of reproductive dysfunction in leaner mice was performed to gain further understanding about the role of intracellular calcium ion signaling in neuronal regulation of reproductive processes in females.
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