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WN1316, A Novel Anti-Oxidant Compound for the Treatment of Leber's Hereditary Optic Neuropathy (LHON)Halas, Sohair January 2016 (has links)
Leber’s Hereditary Optic Neuropathy (LHON) is a devastating mitochondrial disorder that leads to irreversible blindness. A mutation in the mitochondrial ND4 gene causes the majority of cases. Oxidative stress plays a role in disease pathology. WN1316 is a small molecule compound with potent anti-oxidant properties. Using in vitro and in vivo assays, the effectiveness of WN1316 in the treatment of LHON was tested. In vitro, the neuroprotective effects of WN1316 were tested against the oxidative stressors menadione and H2O2. These studies showed that WN1316 can protect SH-SY5Y neuronal cells and 661W photoreceptor-derived cells from oxidative stress in a concentration-dependent manner. Combination therapies with WN1316 and the X-linked Inhibitor of Apoptosis (XIAP) provided even better protection. In vivo, LHON disease had not progressed sufficiently to assess WN1316 effects on retinal function and axon counts. However we saw some delay in disease progression in the WN1316 group using electron microscopy. These initial studies suggest that WN1316 will be effective in the treatment of LHON, but we need to increase the timeline for disease progression to see the full effects of the compound.
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Diagnosis of Leber’s hereditary optic neuropathy (LHON) : analysis of MT-ND1, MT-ND4 and MT-ND6 in patients with LHONÅgersten, Alexandra January 2009 (has links)
<p>Leber´s hereditary optic neuropathy (LHON), a disease affecting vision, is caused by several point mutations in mitochondrial DNA. Mutations leading to a defect NADH ubiquinone oxidoreductase protein will affect the respiratory chain and cause a disturbed ATP production. It is still unknown why this defect leads to the degeneration of retinal ganglion cells and cells in the opticus nerve as well as demyelination of axons in these areas. Analysis of mitochondrial DNA is an important tool in the diagnosis of the disease. At the present time analysis is based on cleavage by restriction enzymes, which only detects two of the most frequent mutations: m.3460G>A and m.11778G>A. This is far too few considering that more than 30 mutations are known to be associated with LHON. Therefore a new analysis method is requested. Here we describe a method based on the sequencing of the mitochondrial genes MT-ND1, MT-ND4 and MT-ND6, which will detect more than 15 different point mutations associated with the disease. To validate the analysis, DNA from 31 patients with LHON symptoms were sequenced; of these 10 were found to be positive for a LHON mutation. This result indicates that the sequencing analysis will be more effective in diagnosis of LHON than restriction enzymes.</p> / <p>Lebers hereditära optikus neuropati (LHON) är en sjukdom som beror på genetiska förändringar i arvsmassan som leder till att cellens energiomsättning rubbas. Detta gör att nervceller i ögat och synnerven bryts ned vilket leder till en synnedsättning. En patient som drabbas av LHON har inga symptom fram till dess att synen börjar försämras. Sjukdomsförloppet går snabbt och på bara några veckor är patienten ofta helt blind. Diagnostik av LHON idag utgörs av flera undersökningar av öga och synfält. Diagnosen bekräftas av en analys av arvsmassan som finns i mitokondrien, cellens energifabrik. Här beskriver vi en ny förbättrad analysmetod baserad på DNA sekvensering, dvs. bestämning av baserna i mitokondriella arvsmassan. För att utvärdera analysen har vi undersökt 31 patienter med misstänkt LHON - av dessa visade sig 10 bära på en sjuklig förändring. Resultatet visar att sekvensering med fördel kan ersätta den tidigare analysmetoden då fler sjukliga förändringar kan påvisas och utförandet av analysen är mer användarvänligt.</p>
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Diagnosis of Leber’s hereditary optic neuropathy (LHON) : analysis of MT-ND1, MT-ND4 and MT-ND6 in patients with LHONÅgersten, Alexandra January 2009 (has links)
Leber´s hereditary optic neuropathy (LHON), a disease affecting vision, is caused by several point mutations in mitochondrial DNA. Mutations leading to a defect NADH ubiquinone oxidoreductase protein will affect the respiratory chain and cause a disturbed ATP production. It is still unknown why this defect leads to the degeneration of retinal ganglion cells and cells in the opticus nerve as well as demyelination of axons in these areas. Analysis of mitochondrial DNA is an important tool in the diagnosis of the disease. At the present time analysis is based on cleavage by restriction enzymes, which only detects two of the most frequent mutations: m.3460G>A and m.11778G>A. This is far too few considering that more than 30 mutations are known to be associated with LHON. Therefore a new analysis method is requested. Here we describe a method based on the sequencing of the mitochondrial genes MT-ND1, MT-ND4 and MT-ND6, which will detect more than 15 different point mutations associated with the disease. To validate the analysis, DNA from 31 patients with LHON symptoms were sequenced; of these 10 were found to be positive for a LHON mutation. This result indicates that the sequencing analysis will be more effective in diagnosis of LHON than restriction enzymes. / Lebers hereditära optikus neuropati (LHON) är en sjukdom som beror på genetiska förändringar i arvsmassan som leder till att cellens energiomsättning rubbas. Detta gör att nervceller i ögat och synnerven bryts ned vilket leder till en synnedsättning. En patient som drabbas av LHON har inga symptom fram till dess att synen börjar försämras. Sjukdomsförloppet går snabbt och på bara några veckor är patienten ofta helt blind. Diagnostik av LHON idag utgörs av flera undersökningar av öga och synfält. Diagnosen bekräftas av en analys av arvsmassan som finns i mitokondrien, cellens energifabrik. Här beskriver vi en ny förbättrad analysmetod baserad på DNA sekvensering, dvs. bestämning av baserna i mitokondriella arvsmassan. För att utvärdera analysen har vi undersökt 31 patienter med misstänkt LHON - av dessa visade sig 10 bära på en sjuklig förändring. Resultatet visar att sekvensering med fördel kan ersätta den tidigare analysmetoden då fler sjukliga förändringar kan påvisas och utförandet av analysen är mer användarvänligt.
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Studium vývojových,biochemických a molekulárních aspektů vybraných vzácných onemocnění v dětském věku / Developmental, pathobiochemical and molecular aspects of selected inborn errors of metabolismKolářová, Hana January 2018 (has links)
Inborn errors of metabolism represent a heterogenous group of rare conditions, most having an incidence of less than 1 in 100,000 births. Because of their low prevalence, they are on the margin of attention of general research and even more so of large pharmaceutical companies. Study of rare diseases is the only way to design therapeutic options in order to improve quality of life of affected patients. Present Thesis particularly focuses on disturbances in mitochondrial energy metabolism. The main goals were the characterization of mitochondrial biogenesis within foetal development, as well as in childhood and adulthood. Another aim was to define clinical, biochemical and molecular aspects of mitochondrial optic neuropathies in childhood and adulthood. This work supported the earlier observations that gestational week 22 is the edge of viability, which has to be taken into account in upcoming discussions about guidelines on resuscitation of preterm neonates. Secondly, over last four years, we managed to examine and describe large cohort of patients with optic neuropathies based on a mitochondrial dysfunction. We have managed to characterize the biochemical and molecular-genetic background in more than 200 patients, and both selected cases (LHON/MELAS overlap syndrome) and cohort studies (MELAS,...
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Enabling massive genomic and transcriptomic analysisStranneheim, Henrik January 2011 (has links)
In recent years there have been tremendous advances in our ability to rapidly and cost-effectively sequence DNA. This has revolutionized the fields of genetics and biology, leading to a deeper understanding of the molecular events in life processes. The rapid advances have enormously expanded sequencing opportunities and applications, but also imposed heavy strains on steps prior to sequencing, as well as the subsequent handling and analysis of the massive amounts of sequence data that are generated, in order to exploit the full capacity of these novel platforms. The work presented in this thesis (based on six appended papers) has contributed to balancing the sequencing process by developing techniques to accelerate the rate-limiting steps prior to sequencing, facilitating sequence data analysis and applying the novel techniques to address biological questions. Papers I and II describe techniques to eliminate expensive and time-consuming preparatory steps through automating library preparation procedures prior to sequencing. The automated procedures were benchmarked against standard manual procedures and were found to substantially increase throughput while maintaining high reproducibility. In Paper III, a novel algorithm for fast classification of sequences in complex datasets is described. The algorithm was first optimized and validated using a synthetic metagenome dataset and then shown to enable faster analysis of an experimental metagenome dataset than conventional long-read aligners, with similar accuracy. Paper IV, presents an investigation of the molecular effects on the p53 gene of exposing human skin to sunlight during the course of a summer holiday. There was evidence of previously accumulated persistent p53 mutations in 14% of all epidermal cells. Most of these mutations are likely to be passenger events, as the affected cell compartments showed no apparent growth advantage. An annual rate of 35,000 novel sun-induced persistent p53 mutations was estimated to occur in sun-exposed skin of a human individual. Paper V, assesses the effect of using RNA obtained from whole cell extracts (total RNA) or cytoplasmic RNA on quantifying transcripts detected in subsequent analysis. Overall, more differentially detected genes were identified when using the cytoplasmic RNA. The major reason for this is related to the reduced complexity of cytoplasmic RNA, but also apparently due (at least partly) to the nuclear retention of transcripts with long, structured 5’- and 3’-untranslated regions or long protein coding sequences. The last paper, VI, describes whole-genome sequencing of a large, consanguineous family with a history of Leber hereditary optic neuropathy (LHON) on the maternal side. The analysis identified new candidate genes, which could be important in the aetiology of LHON. However, these candidates require further validation before any firm conclusions can be drawn regarding their contribution to the manifestation of LHON. / QC 20111115
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Optimization of a Multiplex PCR-RFLP Method Used for Detection of Three Primary Mutations in Leber’s Hereditary Optic Neuropathy PatientsNord, Emilia January 2020 (has links)
Leber’s hereditary optic neuropathy (LHON) is the most commonly inherited disease that causes blindness in one or both eyes, with a minimum prevalence of 1 in 31 000 in the northeast of England. What causes LHON is not fully known but three mitochondrial mutations, G3460A, G11778A, and T14484C, have been identified in over 95 % of all LHON patients. To diagnose LHON, detection methods like sequencing, allele specific polymerase chain reaction and polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) are used to identify these three mutations. The methods are now evolving into multiplex ones to increase efficiency, the aim of this study was therefore to optimize one of them, a multiplex PCR-RFLP method developed in 2015. This study was however not completed, due to the COVID-19 pandemic, but a series of preparatory steps were performed before its termination. DNA extraction was performed, both genomic and plasmid, using a kit and in-house protocols. The DNA was then used for polymerase chain reactions (PCRs), for both the human β-globin gene and for the three mutations, where magnesium concentration and annealing temperature was optimized. This study resulted in clear, high quality extractions, with the kit as the preferable method. It also indicated that a 3 mM magnesium concentration and an annealing temperature of 59 °C was optimal for all mutations when using so called LHON primers. The conditions for the PCR using the multiplex primers might be different, therefore a new study is required to evaluate the multiplex PCR-RFLP method further. / Bakgrund: Lebers hereditära optikusneuropati (LHON) är en vanlig ärftlig sjukdom som orsakar blindhet. LHON orsakas i över 95 % av fallen av en av tre mitokondriella mutationer, där en byggsten i mitokondriens DNA felaktigt bytts ut mot en annan. Dessa mutationer heter G3460A, G11778A och T14484C. För att diagnostisera sjukdomen detekteras mutationerna, bland annat genom att extrahera DNA från blod, DNA som man sedan skapar otaliga kopior av genom en metod som heter ”polymerase chain reaction” (PCR). Dessa kopior kan sedan klyvas i bitar med hjälp av enzym och baserat på fragmentens storlek kan det avgöras om personen har mutationen eller inte, detta kallas för ”restriction fragment length polymorphism” (RFLP). I nuläget letar man efter en mutation i taget men det har utvecklats några metoder där man kan hitta alla mutationer på en gång och den här studiens syfte var att undersöka hur man på bästa sätt kan utföra en av dessa metoder, en så kallad multiplex PCR-RFLP. Metod: Studien avbröts i förtid på grund av ett pandemiskt utbrott av COVID-19 men hann omfatta DNA-extraktion från humant blod och bakterier med hjälp av ett kommersiellt kit och laboratoriets egna protokoll. Även PCR utfördes för en normal genuppsättning och de tre mutationerna. Resultat och slutsats: Extraktionen gav bra resultat med alla metoder men det kommersiella kitet gav bäst resultat. PCR med det DNA som extraherats fungerade bara ibland vilket gjorde det svårt att dra några större slutsatser, oavsett krävs fler studier för att undersöka metoden eftersom arbetet inte kunde slutföras.
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Optimization of a multiplex ARMS-PCR for detection of the primary mutations causing Leber’s hereditary optic neuropathJäder, Klara January 2020 (has links)
Leber’s hereditary optic neuropathy (LHON) is a genetic disease that causes the patients to become blind, first in one eye and then the other, around the ages of 10-75 years. The disease is caused by mutations in the mitochondrial DNA, which disturbs the respiratory chain leading to the deterioration of the retinal ganglion cells. This study’s aim is to optimize a multiplex amplification-refractory mutation system PCR for detection of three primary mutations causing LHON. This was done through a series of PCRs, including PCR aimed at the ß-globin gene, conventional simplex PCR and a simplex ARMS-PCR aimed at the three primary mutations causing LHON. This study was, however, terminated prematurely due the Covid-19 outbreak and the optimization of the ARMS-PCR could therefore not be done. This study’s aim was adapted to the new circumstances to instead provide guidance on how to perform the optimization using the results from the PCRs that were done before the termination. The results found that for the ARMS-PCR 2 mM of magnesium would suffice as a start point overall and the need to solve the problems with the two 14484 plasmids was evident. The ARMS-PCR is one of many methods that can be used to the detect single nucleotide polymorphism, but its availability and robustness makes this a method worth optimizing. To continue with the optimization of the ARMS-PCR several factors would have to be tested, including annealing temperature, primer concentrations and magnesium concentration.
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