Unraveling the Causative Defects in X-linked Myopathy with Excessive Autophagy

Oprea, Iulia

19 February 2010

X-linked myopathy with excessive autophagy (XMEA) is a skeletal muscle disorder inherited in recessive fashion, affecting boys and sparing carrier females. Onset is in childhood with weakness of the proximal muscles of the lower extremities, progressing slowly to involve other muscle groups. Pathological analysis of skeletal muscle biopsies shows no inflammation, necrosis or apoptosis. Instead, forty to 80% of fibers exhibit giant autophagic vacuoles with heterogeneous degradative content. Numerous critical functions of all cells are compartmentalized in particular pH environments established by the intracellular transmembrane V-ATPase proton pump complex. Assembly of this complex, directed by the Vma21p chaperone, is well-studied in yeast but completely unknown in other organisms. The aim of my project was a better understanding of XMEA pathogenesis, with a focus on finding the disease-causing gene. In this thesis, I identify mutations in XMEA patients in a novel, previously uncharacterized gene, which we name VMA21. Most of the mutations are located in splicing-relevant positions and decrease splicing efficiency. After establishing that XMEA is caused by hypomorphic alleles of the VMA21 gene, I show that VMA21 is the diverged human orthologue of the yeast Vma21p protein, and that like Vma21p, it is an essential assembly chaperone of the V-ATPase. Decreased VMA21 reduces V-ATPase activity, resulting in altered lysosomal pH and a blockage at the degradative step of autophagy. Towards understanding disease pathogenesis, I show evidence of compensatory autophagy upregulation consecutive to the impaired clearance. Accumulated autolysosomes due to increased autophagy continue to face the degradative block and are slow to disappear. Instead, they merge to each other and form the characteristic giant XMEA vacuoles. These results uncover a novel mechanism of disease, namely macroautophagic overcompensation leading to cell vacuolation and tissue atrophy. This work describes the clinical outcome at the cusp of tolerable reduction in V-ATPase, with implications on common diseases like osteoporosis and cancer metastasis, where increased V-ATPase activity is an important component. Our XMEA patients show that the safety margin of reducing V-ATPase activity in humans is wide, increasing the potential to utilize chemical or biological V-ATPase inhibitors as possible therapies.

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Efficient Screening of Long Oligonucleotides Against Hundred Thousands of SARS-CoV-2 Genome Sequences

Weidmann, Manfred, Graf, Elena, Lichterfeld, Daniel, Abd El Wahed, Ahmed, Bekaert, Michael

20 January 2024

An unprecedented use of high-throughput sequencing for routine monitoring of SARS-CoV-2 viruses in patient samples has created a dataset of over 6 million SARS-CoV-2 genomes. To monitor genomes, deposited in the GISAID database, and to track the continuous sequence evolution of molecular assay oligonucleotide target sequences. A simple pipeline tool for non-experts was developed to mine this database for nucleotide changes in oligonucleotides and tested with the long oligonucleotides of a Recombinase polymerase amplification (RPA) assay targeting the RNA-dependent RNA polymerase (RdRP) gene of the SARS-CoV-2. Results indicate the emergence of a single nucleotide change in the reverse oligonucleotide from 0.03 to 26.23% (January to May 2021) in Alpha variant genomes, which however reduced to 17.64% by September after which the Alpha variant was completely displaced by the Delta variant. For all other variants, no relevant nucleotide changes were observed. The oligonucleotide screening pipeline allows efficient screening of nucleotide changes in oligonucleotides of all sizes in minutes.

info:eu-repo/classification/ddc/610

ddc:610

Sekvenční varianty genu HNF1B u autozomálně recesivní polycystické choroby ledvin / Sequence variety of HNF1B gene in autosomal recessive polycystic kidney disease

Kavec, Miriam

January 2017

Autosomal recessive polycystic kidney disease (ARPKD) is a rare severe inherited disease manifested by cystic renal disease, congenital hepatic fibrosis and dilatatation of bile ducts. The spectrum of clinical manifestations is very wide and variable, depends on the age at which the disease was manifested. In severe forms of the disease, it is possible to detect the first symptoms prenatally around the 20th week of pregnancy due to increased echogenic kidneys and the presence of oligohydramnios. The causal gene of this disease is thePKHD1 gene with protein product fibrocystin that is most likely contributing on maintaining the intracellular concentration of Ca2+ cations. The exact phatophysiology mechanism of ARPKD remains unknown. Phenotypic manifestations of this disease may overlap with mutations associated with other genes. One of the genes mimicking the ARPKD phenotype is the HNF1B gene. Mutations associated with HNF1B gene are the most common monogenic cause of developmental kidney abnormalities. HNF1B is a tissue-specific transcription factor that regulates the expression of PKHD1. In experimental part I worked on genetic analysis of the HNF1B gene in 28 patients who have not been confirmed ARPKD diagnosis by detection of 2 PKHD1 mutations. For the purposes of mutational screening, I used...