Project description:To understand the common and opposite effects of mitochondrial and lysosomal perturbations on cellular signaling, we performed RNAseq in HeLa cells stably silenced for the mitochondrial respiratory chain subunit UQCRC1 (as a model of chronic mitochondrial respiratory chain deficiency), for lysosomal hydrolase acid alpla-glucosidase (GAA), or for lysosomal cathepsin B (CTSB). The controls were HeLa cells with scrambled shRNA.

Project description:Glycogen storage disease type II (Pompe's disease) is a lysosomal storage disorder which is associated with intralysosomal accumulation of glycogen impais muscle and nerve function. Mice that lack the lysosomal enzyme, acid alpha glucosidase model the human Pompe's disease. To understand signaling mechanisms that could potentially drive the progression of the disease, we employed RNA-Seq to unbiasedly characterize transcriptional changes in the cortex of Gaa-/- mice. We studied Gaa-/- mice and their wild type littermates at 12 months of age and found a robust induction of inflammatory genes in the cortex of Gaa-/- mice.

Project description:Pompe disease (glycogen storage disease type II, or acid maltase deficiency) is an autosomal-recessive disorder of metabolism caused by mutations in the lysosomal hydrolase, acid alpha-glucosidase gene (GAA), resulting in progressive muscle atrophy. Gene therapy is a promising approach to treat genetic diseases, and liver-restricted expression of secretable GAA can produce immune tolerance and improve muscle GAA activity. To further understand the molecular mechanisms underlying Pompe disease and impact of gene therapy, we applied RNA sequencing.

Project description:Pompe disease is a neuromuscular disorder caused by mutations in the gene encoding for the lysosomal enzyme acid α-glucosidase (GAA). GAA converts lysosomal glycogen to glucose, and its deficiency leads to pathologic glycogen accumulation. Enzyme replacement therapy (ERT) is the only available treatment for Pompe disease at the moment with several shortcomings. We have shown that liver expression of secGAA has better therapeutic efficacy than non-engineered GAA after long-term treatment of four months old Gaa-/- mice with low vector doses. Based on those results, we have treated severely affected nine months old Gaa-/- mice with the AAV-secGAA vector and followed the animals for nine months thereafter. At the end of the study, AAV-treated Gaa-/- mice showed complete rescue of the Pompe phenotype. Transcriptomic profiling of skeletal muscle highlighted mitochondrial bioenergetics defects, supported by electron microscopy, western blotting and biochemical findings, which were partially corrected after AAV treatment. Together, these results provide insight into the reversibility of advanced Pompe disease in the Gaa-/- mouse model via liver gene transfer of secGAA.

Project description:While there are many human skeletal muscle disorders, very few therapies have been developed. It has not been possible to generate large amounts of purified skeletal muscle cells from pluripotent stem cells, and to test therapies quantitatively. We therefore devised conditions for generating and expanding purified human myogenic progenitors from induced pluripotent stem (iPS) cells. The progenitors retained the capacity to differentiate into multinucleated myotubes and showed a normal karyotype throughout the expansion phase. We applied this method to Pompe disease, a metabolic myopathy caused by deficiency of the lysosomal enzyme acid alpha-glucosidase (GAA). In a screen, we identified sequences that suppressed aberrant GAA exon 2 splicing caused by the frequent c.-32-13T>G (IVS1) GAA variant. Antisense oligonucleotides (AONs) that blocked these sequences promoted exon 2 inclusion in patient-derived myotubes. As this raised GAA enzymatic activity above the disease threshold, AON-mediated splicing correction may provide a treatment option for Pompe disease.

Project description:Pompe disease (glycogen storage disease type II, or acid maltase deficiency) is an autosomal-recessive disorder of metabolism caused by mutations in the lysosomal hydrolase, acid alpha-glucosidase gene (GAA), resulting in progressive muscle atrophy. The current standard of care treatment, enzyme replacement therapy, consists of delivering recombinant human GAA (rhGAA) to reduce muscle glycogen and improve patient quality of life. With the aim of developing in vitro systems to study human disease and test therapies, we applied RNA sequencing to 3D tissue-engineered human skeletal muscle to compare healthy, (infantile onset) Pompe disease, and rhGAA-treated Pompe engineered tissues.

Project description:<p>Infantile-onset Pompe disease is an inherited disorder that is normally diagnosed within the first months of life. It is caused by lack of or defect in an enzyme (a special protein that carries out normal chemical reactions within the body) called acid alpha-glucosidase (GAA). GAA normally breaks down glycogen (stored sugar) in lysosomes (the part of the cell that digests food and other chemicals). Pompe disease is one of many lysosomal storage diseases (LSDs). LSDs are diseases caused by the malfunction of the lysosome or one of their digestive enzymes. Patients with Pompe disease cannot break down lysosomal glycogen. This causes glycogen to build up and damage cells throughout the body, especially in the heart and muscles.</p> <p>Current treatment for Pompe disease involves enzyme replacement therapy (ERT). In this treatment, the drug alglucosidase alfa (Myozyme) is put into your blood. The drug provides a form of the GAA enzyme to replace the enzyme that is missing or not working properly in the patient&#39;s blood. This treatment has allowed babies to live longer and achieve developmental milestones.</p> <p>In this study, researchers will learn about the patient&#39;s ability to tolerate ERT. Cross-Reactive Immunological Material (CRIM) is a measurement of natural GAA production. A patient&#39;s CRIM status (either positive or negative) is an important factor that affects how he or she responds to ERT with Myozyme. Children who produce some natural GAA are classified as CRIM+, while children who do not produce any natural GAA are classified as CRIM-.</p> <p>Children who are CRIM+ generally tolerate ERT well. But, children who are CRIM-, and some children classified as CRIM+, have a poor response to ERT. Patients who have a poor response to ERT have complications because their body sees Myozyme as "foreign" and triggers an immune response to try to remove it from the body. Treatments are currently being developed to stop this immune response and prevent complications from ERT.</p> <p>We will enroll patients with Infantile Pompe disease in this longitudinal natural history (observational) study. The specific aims of this study are: <ol> <li>To determine and correlate Cross-Reactive Immunological Material (CRIM) status with the GAA gene mutations found on these patients</li> <li>To validate an approach for determining CRIM status from whole blood sample, with the gold standard determination of CRIM status by skin fibroblasts and mutation analysis</li> <li>To explore the clinical treatment response and natural history of CRIM-positive and CRIM-negative Pompe disease patients with and without immune modulation</li> <li>To investigate the role of immune response to treatment</li> </ol> </p>

Project description:Pompe disease (PD) is a neuromuscular disorder caused by deficiency of acid-alpha-glucosidase (GAA), leading to motor and respiratory dysfunctions. Available Gaa knock-out (KO) mouse models do not accurately mimic PD, particularly the highly impaired respiratory phenotype. Methods. Here we developed a new mouse model of PD crossing Gaa KO B6;129 with DBA2/J mice. Findings. Male Gaa KODBA2/J presents most of the key features of the human disease, including early lethality, severe respiratory impairment, cardiac hypertrophy and muscle weakness. Transcriptome analyses of Gaa KODBA2/J, compared to the parental Gaa KOB6;129 mice, revealed a profoundly impaired gene signature in the spinal cord and a similarly deregulated gene expression in skeletal muscle. Muscle and spinal cord transcriptome changes in Gaa KODBA2/J, were significantly improved upon gene therapy with AAV vectors expressing a secreted GAA enzyme.

Project description:Acid alpha-glucosidase (GAA) is a lysosomal glycogen-catabolizing enzyme, a deficiency in which leads to Pompe disease. Pompe disease can be treated with systemic recombinant human GAA (rhGAA) enzyme replacement therapy (ERT), but the current standard of care has poor uptake in skeletal muscles, limiting clinical efficacy. Further, it is unclear how the specific cellular processing steps of GAA post-delivery to lysosomes impact efficacy. GAA undergoes both proteolytic cleavage and glycan trimming within the endolysosomal pathway, yielding a more active enzyme for hydrolyzing its natural substrate glycogen. The relative contributions for each of these processing steps for increasing rhGAA glycogen hydrolytic activity are unclear. Here, we developed a tool kit of modified rhGAAs that allowed us to dissect the individual contributions of glycan trimming and proteolysis on maturation-associated increases in hydrolytic activity on glycogen. Chemical modifications of terminal sialic acids on N-glycans blocked sialidase activity in vitro and in cellulo, thereby preventing downstream glycan trimming without affecting proteolysis. This sialidase-resistant rhGAA displayed only partial activation following endolysosomal processing, as evidenced by lower catalytic efficiency on glycogen. We also generated enzymatically deglycosylated rhGAA that was shown to be partially activated despite not undergoing proteolytic processing. Taken together, these data suggest that an optimal rhGAA ERT would require both N-glycan and proteolytic processing to attain the most efficient enzyme kinetics for glycogen hydrolysis.

Project description:Gemcitabine treatment shifts the intestinal microbiota of PC mice towards an inflammatory profile which may worsen mucositis and side effects observed upon chemotherapy. We explored the effect of a specific probiotics blend administered, with or without gemcitabine treatment, to PC xenografted mice.